Aromatic amino acids in the finger domain of the FMRFamide-gated Na[Formula: see text] channel are involved in the FMRFamide recognition and the activation.

FMRFamide-gated Na[Formula: see text] channel (FaNaC) is a member of the DEG/ENaC family and activated by a neuropeptide, FMRFamide. Structural information about the FMRFamide-dependent gating is, however, still elusive. Because two phenylalanines of FMRFamide are essential for the activation of FaNaC, we hypothesized that aromatic-aromatic interaction between FaNaC and FMRFamide is critical for FMRFamide recognition and/or the activation gating. Here, we focused on eight conserved aromatic residues in the finger domain of FaNaCs and tested our hypothesis by mutagenic analysis and in silico docking simulations. The mutation of conserved aromatic residues in the finger domain reduced the FMRFamide potency, suggesting that the conserved aromatic residues are involved in the FMRFamide-dependent activation. The kinetics of the FMRFamide-gated currents were also modified substantially in some mutants. Some results of docking simulations were consistent with a hypothesis that the aromatic-aromatic interaction between the aromatic residues in FaNaC and FMRFamide is involved in the FMRFamide recognition. Collectively, our results suggest that the conserved aromatic residues in the finger domain of FaNaC are important determinants of the ligand recognition and/or the activation gating in FaNaC.

Modulation of the FMRFamide-gated Na+ channel by external Ca2.

FMRFamide-gated Na+ channel (FaNaC) is a member of the DEG/ENaC family. Amino acid sequence of the second transmembrane region (TM2) of FaNaC is quite similar to that of the acid-sensing ion channels (ASIC) of the same family. In the upper part of TM2, there are two aspartate residues (D552 and D556 in Aplysia FaNaC, AkFaNaC) which construct two negative rings in the external vestibule. In the present study, we examined the function of D552/D556 mutants of AkFaNaC in Xenopus oocytes with special interest in Ca2+ sensitivity of FaNaC. The FMRFamide-evoked current through AkFaNaC was depressed by submillimolar Ca2+ such that the current in Ca2+-free condition was 2-3-fold larger than that in the control solution which contained 1.8 mM CaCl 2. Both D552 and D556 were found to be indispensable for the sensitivity of FaNaC to submillimolar Ca2+. Unexpectedly, however, both acidic residues were not essential for the inhibition by millimolar Ca2+ concentrations. The Ca2+-sensitive gating of FaNaC was recapitulated by an allosteric model in which Ca2+-bound channels are more difficult to open. The desensitization of FaNaC was also inhibited by Ca2+, which was abolished in some D552/D556 mutants. Structural models of FaNaC made by homology modeling showed that the distance between oxygen atoms of D552 and D556 on the adjacent subunits is close enough to coordinate Ca2+ in the nonconducting desensitized channel but not in the open channel. The results suggest that Ca2+ coordination between oxygen atoms of D552 and D556 disturbs the opening transition as well as the desensitization of FaNaC.

Serotonin modulates the excitatory synaptic transmission in the dentate granule cells.

Serotonergic fibers from the raphe nuclei project to the hippocampal formation, the activity of which is known to modulate the inhibitory interneurons in the dentate gyrus. On the other hand, serotonergic modulation of the excitatory synapses in the dentate gyrus is not well examined. In the present study, we examined the effects of 5-HT on the excitatory postsynaptic potentials (EPSPs) in the dentate granule cells evoked by the selective stimulation of the lateral perforant path (LPP), the medial perforant path (MPP), or the mossy cell fibers (MCF). 5-HT depressed the amplitude of unitary EPSPs (uEPSPs) evoked by the stimulation of LPP or MPP, whereas uEPSPs evoked by MCF stimulation were little affected. The effect was partly explained by the decrease of the resting membrane resistance following the activation of 5-HT1A receptors, which was confirmed by computer simulations. We also found that the probability of evoking uEPSP by LPP stimulation but not MPP or MCF stimulation was reduced by 5-HT and that the paired-pulse ratio of LPP-evoked EPSP but not that of MPP- or MCF-evoked ones was increased by 5-HT. These effects were blocked by 5-HT2 antagonist, suggesting that the transmitter release in the LPP-granule cell synapse is inhibited by the activation of 5-HT2 receptors. The present results suggest that 5-HT can modulate the EPSPs in the dentate granule cells by at least two distinct mechanisms.

Molecular cloning of precursors for TEP-1 and TEP-2: The GGNG peptide-related peptides of a prosobranch gastropod, Thais clavigera.

TEP (Thais excitatory peptide)-1 and TEP-2 are molluscan counterparts of annelidan GGNG-peptides, identified in a neogastropod, Thais clavigera (Morishita et al., 2006). We have cloned two cDNAs encoding TEP-1 and TEP-2 precursor protein, respectively, by the standard molecular cloning techniques. Predicted TEP-1 precursor protein consists of 161 amino acids, while predicted TEP-2 precursor protein has 118 amino acids. Only a single copy of TEP was found on the respective precursor. The semi-quantitative RT-PCR showed that expression of TEP-1 was high in sub-esophageal, pleural, pedal and visceral ganglia, while it was low in supra-esophageal ganglion. By contrast, expression level of TEP-2 was high in pedal and visceral ganglia. In situ hybridization visualized different subsets of TEP-1 and TEP-2 expressing neurons in Thais ganglia. For example, supra-esophageal ganglion contained many TEP-2 expressing neuron, but not TEP-1 expressing ones. These results suggest that expression of TEP-1 and TEP-2 is differently regulated in the Thais ganglia.

Systemic angiotensin II and exercise-induced neurogenesis in adult rat hippocampus.

Physical exercise is a robust stimulus that enhances hippocampal neurogenesis via cell proliferation in rodents. We examined the role of systemic angiotensin (Ang) peptides in exercise-dependent enhancement of neurogenesis in the adult rat hippocampus. Plasma angiotensin peptide concentration increased rapidly in response to 30 min of treadmill exercise. After undertaking this exercise once daily for a week, the number of proliferating cells in the hippocampus, identified by 5-bromo-2'-deoxyuridine (BrdU) incorporation, had increased compared with controls. To mimic the increase in plasma Ang peptide concentrations brought about by exercise, rats were injected with 10(-5)M Ang II once daily for a week. The number of BrdU-incorporating cells and of doublecortin (DCX)-expressing immature neurons in the hippocampus rose approximately 1.5 and 1.9-fold compared with controls, respectively. The effects were completely abolished by an Ang II receptor subtype 1 antagonist losartan. These findings, taken together, suggest that an increased concentrations of Ang peptides in the systemic circulation during exercise may promote neurogenesis in the adult rat hippocampus.

Electrostatic charge at position 552 affects the activation and permeation of FMRFamide-gated Na+ channels.

The FMRFamide-gated Na(+) channel (FaNaC) is a unique peptide-gated sodium channel and a member of the epithelial sodium channel/degenerin family. Previous studies have shown that an aspartate residue (Asp(552)) in the second transmembrane domain is involved in activation of the FaNaC. To examine the significance of a negative charge at position 552, we used a cysteine-modification method. Macroscopic currents of a cysteine mutant (D552C) were potentiated or inhibited by use of positively or negatively charged sulfhydryl reagents ([2-(trimethylammonium)ethyl]methanethiosulfonate bromide, MTSET, and sodium (2-sulfonatoethyl)methanethiosulfonate, MTSES, respectively). Dose-response analysis showed that treatment with MTSET increased the potency of the FMRFamide in the FaNaC whereas treatment with MTSES reduced the maximum response. Negative charge at position 552 was necessary for the characteristic inward rectification of the FaNaC. These results suggest that negative electric charge at position 552 is important to the activation and permeation properties of the FaNaC.

Molecular cloning of two distinct precursor genes of NdWFamide, a d-tryptophan-containing neuropeptide of the sea hare, Aplysia kurodai.

NdWFamide (NdWFa) is a D-tryptophan-containing cardioexcitatory neuropeptide in gastropod mollusks, such as Aplysia kurodai and Lymanea stagnalis. In this study, we have cloned two cDNA encoding distinct precursors for NdWFa from the abdominal ganglion of A. kurodai. One of the predicted precursor proteins consisted of 90 amino acids (NWF90), and the other consisted of 87 amino acids (NWF87). Both of the predicted precursor proteins have one NWFGKR sequence preceded by the N-terminal signal peptide. Sequential double staining by in situ hybridization (ISH) and immunostaining with anti-NdWFa antibody suggested that NdWFa-precursor and NdWFa peptide co-exist in neurons located in the right-upper quadrant region of the abdominal ganglion. In ISH, NWF90-specific signal and NWF87-specific one were found in different subsets of neurons in the abdominal ganglia of Aplysia. The expression level of NWF90 gene estimated by RT-PCR is much higher than that of NWF87 gene. These results suggest that NWF90 precursor is the major source of NdWFa in Aplysia ganglia.

Position 552 in a FMRFamide-gated Na(+) channel affects the gating properties and the potency of FMRFamide.

FMRFamide-gated Na(+) channel (FaNaC) is a peptide-gated sodium channel in the epithelial Na(+) channel/degenerin family. Although there are some data on the location of the putative peptide binding site, there is no structural information on the activation gating of FaNaC. Here, we addressed the function of a conserved aspartate residue in the second transmembrane domain of FaNaC. We used Aplysia kurodai FaNaC (AkFaNaC) and examined the function of the aspartate (D552) by site-directed mutagenesis and electrophysiological recording in Xenopus oocytes. We found that the macroscopic activation, desensitization, and potency of FMRFamide and its modification by external Ca(2+) and Mg(2+) are greatly affected by physicochemical properties of the amino acid at position 552. We conclude that D552 is situated in a key position that affects the gating properties of FaNaC.

Molecular cloning and functional characterization of the Aplysia FMRFamide-gated Na+ channel.

FMRFamide-gated Na+ channel (FaNaC) is the only known peptide-gated ion channel, which belongs to the epithelial Na+ channel/degenerin (ENaC/DEG) family. We have cloned a putative FaNaC from the Aplysia kurodai CNS library using PCR, and examined its characteristics in Xenopus oocytes. A. kurodai FaNaC (AkFaNaC) comprised with 653 amino acids, and the sequence predicts two putative membrane domains and a large extracellular domain as in other members of the ENaC/DEG family. In oocytes expressing AkFaNaC, FMRFamide evoked amiloride-sensitive Na+ current. Different from the known FaNaCs (Helix and Helisoma FaNaCs), AkFaNaC was blocked by external Ca2+ but not by Mg2+. Also, desensitization of the current was enhanced by Mg2+ but not by Ca2+. The FMRFamide-gated current was depressed in both low and high pH. These results indicate that AkFaNaC is an FaNaC of Aplysia, and that the channel has Aplysia specific functional domains.

Peptidergic innervation of the vasoconstrictor muscle of the abdominal aorta in Aplysia kurodai.

The arterial system of the marine mollusc Aplysia consists of three major arteries. One of them, the abdominal aorta, has a sphincter (the vasoconstrictor muscle) at the base of the artery. Contraction of this muscle reduces the blood flow into the abdominal aorta, thereby, playing a role in the regulation of the blood distribution in Aplysia. Here, we show the contractility of the vasoconstrictor muscle is modulated by three types of endogenous peptides, Aplysia mytilus inhibitory peptide-related peptides (AMRP), enterin and NdWFamide. Immunohistochemistry showed that putative neuronal processes containing the three peptides exist in the vasoconstrictor muscle. Enterin inhibited the muscle contraction elicited by the nerve stimulation or the application of a putative excitatory transmitter, acetylcholine (ACh). Enterin hyperpolarized the resting potential of the muscle and decreased the amplitude of the excitatory junction potential (EJP). AMRP also inhibited the nerve-evoked contraction although its action on the ACh-induced contraction was variable. AMRP also reduced the size of EJP, but had no effect on the resting potential of the muscle. NdWFamide enhanced the nerve-evoked contraction but not the ACh-induced contraction. NdWFamide augmented EJP without affecting the resting potential of the muscle. These results suggest that AMRP, enterin and NdWFamide are endogenous modulators of the contractile activity of the vasoconstrictor muscle, and that the peptidergic innervations of this muscle contribute to fine tuning of the blood distribution in Aplysia.

Solution structure of ADO1, a toxin extracted from the saliva of the assassin bug, Agriosphodrus dohrni.

ADO1 is a toxin purified from the saliva of the assassin bug, Agriosphodrus dohrni. Because of its similarity in sequence to Ptu1 from another assassin bug, we did not assess its pharmacologic target. Here, we demonstrate by electrophysiologic means that ADO1 targets the P/Q-type voltage-sensitive calcium channel. We also determine the solution structure of ADO1 using two-dimensional NMR techniques, followed by distance geometry and molecular dynamics. The structure of ADO1 belongs to the inhibitory cystine knot (ICK) structural family (i.e., a compact disulfide-bonded core from which four loops emerge). ADO1 contains a two-stranded, antiparallel beta-sheet structure. We compare the structure of ADO1 with other voltage-sensitive calcium-channel blockers, analyze the topologic juxtaposition of key functional residues, and conclude that the recognition of voltage-sensitive calcium channels by toxins belonging to the ICK structural family requires residues located on two distinct areas of the molecular surface of the toxins.

Cloning of Octopus cephalotocin receptor, a member of the oxytocin/vasopressin superfamily.

We reported that the common octopus, Octopus vulgaris, in common with vertebrates, possesses two members of the oxytocin/vasopressin superfamily: octopressin (OP) and cephalotocin (CT). This was the first observation of its kind in invertebrates. As OP and CT have different biological activities, the presence of specific receptors has been proposed. We cloned the cDNA of an orphan receptor from Octopus brain and found it to encode a polypeptide of 397 amino acids that displays sequences characteristic of G-protein coupled receptors. The orphan receptor showed high homology to receptors of the oxytocin/vasopressin superfamily and seemed to conserve the agonist-binding pocket common to the oxytocin and vasopressin receptors. Xenopus oocytes that express the orphan receptor responded to the application of CT by an induction of membrane Cl(-) currents coupled to the inositol phosphate/Ca(2+) pathway. OP and the other members of the oxytocin/vasopressin superfamily did not activate this receptor. HPLC fractionation of the Octopus brain extract combined with an oocyte assay yielded a single substance that was identical to CT. On the basis of these results, we conclude that the cloned receptor is the CT receptor (CTR). Expression of CTR mRNA in Octopus was detected in the central and the peripheral nervous systems, the pancreas, the oviduct and the ovary. This receptor may mediate physiological functions of CT in Octopus such as neurotransmission, reproduction and metabolism.

Distribution of the Aplysia cardioexcitatory peptide, NdWFamide, in the central and peripheral nervous systems of Aplysia.

NdWFamide is an Aplysia cardioexcitatory tri-peptide containing D-tryptophan. To investigate the roles of this peptide, we examined the immunohistochemical distribution of NdWFamide-positive neurons in Aplysia tissues. All the ganglia of the central nervous system (CNS) contained NdWFamide-positive neurons. In particular, two left upper quadrant cells in the abdominal ganglion, and the anterior cells in the pleural ganglion showed extensive positive signals. NdWFamide-positive processes were observed in peripheral tissues, such as those of the cardio-vascular system, digestive tract, and sex-accessory organs, and in the connectives or neuropils in the CNS. NdWFamide-positive neurons were abundant in peripheral plexuses, such as the stomatogastric ring. To examine the NdWFamide contents of tissues, we fractionated peptidic extracts from the respective tissues by reversed-phase high-pressure liquid chromatography and then assayed the fractions by competitive enzyme-linked immunosorbent assay. A fraction corresponding to the retention time of synthetic NdWFamide contained the most immunoreactivity, indicating that the tissues contained NdWFamide. The prevalence of the NdWFamide content was roughly in the order: abdominal ganglion >heart >gill >blood vessels >digestive tract. In most of the tissues containing NdWFamide-positive nerves, NdWFamide modulated the motile activities of the tissues. Thus, NdWFamide seems to be a versatile neurotransmitter/modulator of Aplysia and probably regulates the physiological activities of this animal.

Structural and functional diversities of the Aplysia Mytilus inhibitory peptide-related peptides.

Aplysia Mytilus inhibitory peptide-related peptides (AMRPs) are multiple hexapeptides coded on a single precursor. By comparing the AMRP precursors of two species of Aplysia (Aplysia californica and Aplysia kurodai), we found that there are substantial numbers of species-specific AMRPs. We next compared the function of AMRPs on the anterior aorta between A. kurodai and Aplysia juliana. In A. juliana, AMRPs inhibited the contractile activity of the aorta (EC(50)=10(-9) to 10(-8)M), whereas the peptides had no obvious action in A. kurodai up to 10(-7)M. These results indicate that AMRPs are both structurally and functionally diverse neuropeptides even among closely related species.

Aplysia cardioactive peptide (NdWFamide) enhances the L-type Ca2+ current of Aplysia ventricular myocytes.

NdWFamide is a D-amino acid containing tripeptide purified from Aplysia heart. Although the cardioexcitatory action of NdWFamide is well established, little is known about how the excitatory action is induced. To examine the action of the peptide on the ion channels expressed in the Aplysia heart muscles, we carried out whole cell clamp experiments in the isolated Aplysia ventricular myocytes. We found that the high voltage-activated (HVA) Ca(2+) current of Aplysia ventricular myocytes is mostly a nifedipine-sensitive L-type current, and that the current was enhanced by NdWFamide via the activation of G proteins.

The enterins inhibit the contractile activity of the anterior aorta of Aplysia kurodai.

The anterior aorta is one of the largest blood vessels in the marine mollusc Aplysia kurodai. We examined the actions of recently identified neuropeptides, the enterins, on this blood vessel. Immunohistochemistry revealed that the enterin-immunopositive nerve fibers and varicosity-like structures are abundant in the aorta. When the enterins were applied to the aorta, the basal tonus of the arterial muscles was diminished. The enterins also decreased the contraction amplitude of the anterior aorta evoked either by the application of an Aplysia cardioactive peptide, NdWFamide, or by the stimulation of a nerve innervating the aorta (the vulvar nerve). We found that the enterins activate the 4-aminopyridine (4-AP)-sensitive K(+) channels, and thereby hyperpolarize the membrane potential of the aortic muscles. In the presence of 4-AP, the enterins failed to inhibit the muscle contraction evoked by the vulvar nerve stimulation, suggesting that the inhibition is mainly due to the activation of the 4-AP-sensitive K(+) channels. The inhibition of the NdWFamide-evoked contraction by the enterin was not, however, affected by 4-AP. These results suggest that the enterins are involved in inhibitory regulation of the contractile activity of the anterior aorta, and that the inhibition could be due to multiple mechanisms.

A novel tachykinin-related peptide receptor. Sequence, genomic organization, and functional analysis.

Structurally tachykinin-related peptides have been isolated from various invertebrate species and shown to exhibit their biological activities through a G-protein-coupled receptor (GPCR) for a tachykinin-related peptide. In this paper, we report the identification of a novel tachykinin-related peptide receptor, the urechistachykinin receptor (UTKR) from the echiuroid worm, Urechis unitinctus. The deduced UTKR precursor includes seven transmembrane domains and typical sites for mammalian tachykinin receptors and invertebrate tachykinin-related peptide receptors. A functional analysis of the UTKR expressed in Xenopus oocytes demonstrated that UTKR, like tachykinin receptors and tachykinin-related peptide receptors, activates calcium-dependent signal transduction upon binding to its endogenous ligands, urechistachykinins (Uru-TKs) I-V and VII, which were isolated as Urechis tachykinin-related peptides from the nervous tissue of the Urechis unitinctus in our previous study. UTKR responded to all Uru-TKs equivalently, showing that UTKR possesses no selective affinity with Uru-TKs. In contrast, UTKR was not activated by substance P or an Uru-TK analog containing a C-terminal Met-NH2 instead of Arg-NH2. Furthermore, the genomic analysis revealed that the UTKR gene, like mammalian tachykinin receptor genes, consists of five exons interrupted by four introns, and all the intron-inserted positions are completely compatible with those of mammalian tachykinin receptor genes. These results suggest that mammalian tachykinin receptors and invertebrate tachykinin-related peptide receptors were evolved from a common ancestral GPCR gene. This is the first identification of an invertebrate tachykinin-related peptide receptor from other species than insects and also of the genomic structure of a tachykinin-related peptide receptor gene.

Cumulative inactivation and the pore domain in the Kv1 channels.

AKv1.1a is an Aplysia Kv1 channel close to a mammalian Kv1.4. Both channels show a prominent frequency-dependent cumulative inactivation. The cumulative inactivation of AKv1.1a but not of rKv1.4 was enhanced by the patch excision. To gain structural information about the phenomenon, we examined chimeras of AKv1.1a and rKv1.4. Chimeras with the AKv1.1a pore domain displayed enhanced cumulative inactivation after patch excision. In the pore domain, eight amino acids are different between the two channels. We, therefore, constructed eight mutants of AKv1.1a (A378E, D379P, Q380T, K384Q, R406K, G409T, W411G, L414I) based on the sequence differences. All the mutants showed a similar macroscopic current decay, suggesting that N-type inactivation was not affected. The patch excision failed to enhance the cumulative inactivation in A378E, D379P, G409T, and L414I. P/C-type inactivation in N-terminal deletion mutants (Delta N) became slower in A378E, D379P, G409T and L414I. Internal application of the N-terminal peptide from the ShB channel induces a frequency-dependent block of Delta N-AKv1.1a. By contrast, the block was not frequency dependent in Delta N-A378E, Delta N-D379P and Delta N-G409T. The results suggest that the positions 378, 379, 409, and perhaps 414 in the AKv1.1a backbone are involved in the stability of P/C-type inactivation and the cumulative inactivation of Kv1 channels.