Molecular cloning of myomodulin cDNA, a neuropeptide precursor gene expressed in neuron L10 of Aplysia californica

Identification and functional characterization of the first molluscan neuromedin U receptor in the slug, Deroceras reticulatum

Neuromedin U (NmU) is a neuropeptide regulating diverse physiological processes. The insect homologs of vertebrate NmU are categorized as PRXamide family peptides due to their conserved C-terminal end. However, NmU homologs have been elusive in Mollusca, the second largest phylum in the animal kingdom. Here we report the first molluscan NmU/PRXamide receptor from the slug, Deroceras reticulatum. Two splicing variants of the receptor gene were functionally expressed and tested for binding with ten endogenous peptides from the slug and some insect PRXamide and vertebrate NmU peptides. Three heptapeptides (QPPLPRYa, QPPVPRYa and AVPRPRIa) triggered significant activation of the receptors, suggesting that they are true ligands for the NmU/PRXamide receptor in the slug. Synthetic peptides with structural modifications at different amino acid positions provided important insights on the core moiety of the active peptides. One receptor variant always exhibited higher binding activity than the other variant. The NmU-encoding genes were highly expressed in the slug brain, while the receptor gene was expressed at lower levels in general with relatively higher expression levels in both the brain and foot. Injection of the bioactive peptides into slugs triggered defensive behavior such as copious mucus secretion and a range of other anomalous behaviors including immobilization, suggesting their role in important physiological functions.

Multifaceted Expression of Peptidergic Modulation in the Feeding System of Aplysia

Neuropeptides are present in species throughout the animal kingdom and generally exert actions that are distinct from those of small molecule transmitters. It has, therefore, been of interest to define the unique behavioral role of this class of substances. Progress in this regard has been made in experimentally advantageous invertebrate preparations. We focus on one such system, the feeding circuit in the mollusc Aplysia. We review research conducted over several decades that played an important role in establishing that peptide cotransmitters are released under behaviorally relevant conditions. We describe how this was accomplished. For example, we describe techniques developed to purify novel peptides, localize them to identified neurons, and detect endogenous peptide release. We also describe physiological experiments that demonstrated that peptides are bioactive under behaviorally relevant conditions. The feeding system is like others in that peptides exert effects that are both convergent and divergent. Work in the feeding system clearly illustrates how this creates potential for behavioral flexibility. Finally, we discuss experiments that determined physiological consequences of one of the hallmark features of peptidergic modulation, its persistence. Research in the feeding system demonstrated that this persistence can change network state and play an important role in determining network output.

Identification and Characterization of Neuropeptides by Transcriptome and Proteome Analyses in a Bivalve Mollusc Patinopecten yessoensis

Neuropeptides play essential roles in regulation of reproduction and growth in marine molluscs. But their function in marine bivalves – a group of animals of commercial importance – is largely unexplored due to the lack of systematic identification of these molecules. In this study, we sequenced and analyzed the transcriptome of nerve ganglia of Yesso scallop Patinopecten yessoensis, from which 63 neuropeptide genes were identified based on BLAST and de novo prediction approaches, and 31 were confirmed by proteomic analysis using the liquid chromatography-tandem mass spectrometry (LC-MS/MS). Fifty genes encode known neuropeptide precursors, of which 20 commonly exist in bilaterians and 30 are protostome specific. Three neuropeptides that have not yet been reported in bivalves were identified, including calcitonin/DH31, lymnokinin and pleurin. Characterization of glycoprotein hormones, insulin-like peptides, allatostatins, RFamides, and some reproduction, cardioactivity or feeding related neuropeptides reveals scallop neuropeptides have conserved molluscan neuropeptide domains, but some (e.g., GPB5, APGWamide and ELH) are characterized with bivalve-specific features. Thirteen potentially novel neuropeptides were identified, including 10 that may also exist in other protostomes, and 3 (GNamide, LRYamide, and Vamide) that may be scallop specific. In addition, we found neuropeptides potentially related to scallop shell growth and eye functioning. This study represents the first comprehensive identification of neuropeptides in scallop, and would contribute to a complete understanding on the roles of various neuropeptides in endocrine regulation in bivalve molluscs.

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.

From precursor to final peptides: a statistical sequence-based approach to predicting prohormone processing

Predicting the final neuropeptide products from neuropeptides genes has been problematic because of the large number of enzymes responsible for their processing. The basic processing of 22 Aplysia californica prohormones representing 750 cleavage sites have been analyzed and statistically modeled using binary logistic regression analyses. Two models are presented that predict cleavage probabilities at basic residues based on prohormone sequence. The complex model has a correct classification rate of 97%, a sensitivity of 97%, and a specificity of 96% when tested on the Aplysia dataset.

Identification of GYRKPPFNGSIFamide (crustacean-SIFamide) in the crayfish Procambarus clarkii by topological mass spectrometry analysis

A new concept relating to the purification protocol for biological proteins and peptides has been designed as "topological mass spectrometry analysis," in combination with MALDI-TOF MS using slices of tissues, chromatographic purification from the extract of tissues, molecular cloning for the determination of the precursor structure, and capillary LC-MS/MS analysis for elucidation of its posttranslational modifications. In an actual application, we identified an alpha-amidated neuropeptide from the red swamp crayfish (Procambarus clarkii) brain. Initially, an MS number of around m/z 1382 was found by the direct MALDI-TOF MS analysis with slices of the accessory lobe of the brain. After two steps of reversed-phase HPLC separation with brain extract, the structure of a 1381 Da peptide was sequenced to the GYRKPPFNGSIFamide (named crustacean-SIFamide). Subsequently, the cDNA has been characterized and encodes a 76 amino acid precursor protein that contains a signal sequence, one copy of GYRKPPFNGSIFG and one additional peptide. The RT-PCR analysis implied that the mRNA of the neuropeptide was expressed throughout the nervous system of the crayfish. Furthermore, immunostaining demonstrated that the neuropeptide is distributed in the olfactory lobe, accessory lobe, olfactory globular tract, and olfactory lobe cells. In addition, database searches revealed that there are homologous sequences of the AYRKPPFNGSIFamide in the genome library of fruitfly Drosophila melanogaster and AYRKPPFNGSLFamide isolated from the grey fleshfly Neobellieria bullata, and GYRKPPFNGSIFamide isolated from the giant tiger prawn Penaeus monodon. These results suggested that the neuropeptide family might be widely distributed in arthropods and plays a significant role in the nervous system.

A novel GGNG-related neuropeptide from the polychaete Perinereis vancaurica

The GGNG peptides are myoactive peptides so far identified from earthworms and leeches, which are the earthworm excitatory peptides (EEP) and the leech excitatory peptide (LEP), respectively. A novel GGNG peptide was isolated and structurally determined from a marine polychaete, Perinereis vancaurica, using a combination of immunological assay and high performance liquid chromatography (HPLC). The peptide was a pentadecapeptide whose amino acid sequence was similar to that of EEP and LEP, and showed myoactivity on isolated esophagus of P. vancaurica with a threshold concentration of 10(-10)M. The peptide was designated as polychaete excitatory peptide (PEP). Amidation of the alpha-carboxyl group of C-terminal residue occurred in PEP. This is the case for LEP, but not for EEP. The cDNA cloning revealed that the structure of the PEP precursor is more similar to the EEP precursor than to the LEP precursor. Immunohistochemical staining showed the presence of PEP in several neurons of central nervous system (CNS) as somata and neuropile structure, epithelial cells of the pharynx and epidermal cells throughout the body wall. Altogether these results support the physiological significance of PEP in regulation of the CNS neural activity and the peripheral myoactivity.

Neuropeptide amidation: cloning of a bifunctional alpha-amidating enzyme from Aplysia

One of the most common mechanisms of posttranslational modifications to generate biologically active (neuro)peptides is the process of peptide alpha-amidation. The only enzyme known to catalyze this important modification is peptidylglycine alpha-amidating monooxygenase (PAM): a (bifunctional) zymogen, giving rise to a monooxygenase (PHM) and a lyase (PAL). The highly peptidergic central nervous system and endocrine system of the marine mollusk Aplysia has homologs of various mammalian peptide processing enzymes, including furin, Afurin2, prohormone convertase 1 (PC1), PC2, carboxypeptidase E (CPE) and CPD. Previously, it has been shown that the abdominal ganglion of Aplysia, which contains approximately 800 peptidergic bag cell neurons, contains the highest specific alpha-amidating activity. We have identified and cloned multiple overlapping central nervous system and bag cell cDNAs that encode a predicted 748-residue protein that is a member of the PAM family. The protein sequence contains the contiguous sequence of the catalytic domains of PHM and PAL, clearly demonstrating the existence of bifunctional Aplysia PAM, the first invertebrate PAM zymogen with an organization similar to that in vertebrates. None of the characterized clones encoded the so-called exon A domain between the PHM and PAL domains. Furthermore, in a specific search by reverse transcription-polymerase chain reaction of RNA from multiple tissues we could only detect exon A-less transcripts. PAM expression was detected in the central nervous system, and in several endocrine and exocrine organs. Aplysia PAM is a candidate prohormone processing enzyme that plays an important role in the processing of Aplysia prohormones in the secretory pathway.

Identification of orcokinin gene-related peptides in the brain of the crayfish Procambarus clarkii by the combination of MALDI-TOF and on-line capillary HPLC/Q-Tof mass spectrometries and molecular cloning

We developed a strategy for the exploration of brain peptides in the red swamp crayfish, Procambarus clarkii, utilizing the combined techniques of matrix-assisted laser desorption/ionization with time-of-flight mass spectrometry (MALDI-TOF MS), molecular cloning, and on-line capillary reversed-phase HPLC/quadrupole orthogonal acceleration time-of-flight (Q-Tof)-MS. We initially performed direct MALDI-TOF MS analysis with slices of the brain. The MS spectra from a slice of the olfactory lobe indicated that an orcokinin (NFDEIDRSGFGFN) occurs in this species. Subsequently, its occurrence was confirmed by molecular cloning of the cDNAs encoding the precursor protein of orcokinin. The deduced amino acid sequences indicated that there are two different types of preproorcokinins. Preproorcokinin A (251 residues long) contains not only seven copies of orcokinin but also two copies of NFDEIDRSGFGFV and one copy each of NFDEIDRSGFGFA, NFDEIDRTGFGFH, and FDAFTTGFGHS. The former three peptides were previously isolated from another crayfish, Orconectes limosus, and/or the shore crab, Carcinus maenas, and the latter two were novel. Preproorcokinin B (266) harbors one additional orcokinin. All sequences of the peptides are flanked by dibasic sequences which are the consensus signal for processing. Moreover, brain extract was subjected to Sephadex G-25 and, subsequently, to on-line capillary reversed-phase HPLC/Q-Tof MS analysis. From the LC-MS analysis, the molecular weights of orcokinin, NFDEIDRSGFGFV, NFDEIDRSGFGFA, NFDEIDRTGFGFH, and FDAFTTGFGHS were identified as the doubly charged ions at m/z 759.37, 751.92, 737.86, 777.90, and 593. 78, respectively. In addition, the sequences were assigned by the collision-induced dissociation spectra using the doubly charged ions in the LC-MS/MS analysis. These data suggest that orcokinin and its related peptides are especially abundant in the olfactory lobe and are synthesized and processed from the two types of preproorcokinins in the crayfish brain.

Functional redundancy of FMRFamide-related peptides at the Drosophila larval neuromuscular junction

The Drosophila FMRFamide gene encodes multiple FMRFamide-related peptides. These peptides are expressed by neurosecretory cells and may be released into the blood to act as neurohormones. We analyzed the effects of eight of these peptides on nerve-stimulated contraction (twitch tension) of Drosophila larval body-wall muscles. Seven of the peptides strongly enhanced twitch tension, and one of the peptides was inactive. Their targets were distributed widely throughout the somatic musculature. The effects of one peptide, DPKQDFMRFamide, were unchanged after the onset of metamorphosis. The seven active peptides showed similar dose-response curves. Each had a threshold concentration near 1 nM, and the EC50 for each peptide was approximately 40 nM. At concentrations <0.1 microM, the responses to each of the seven excitatory peptides followed a time course that matched the fluctuations of the peptide concentration in the bath. At higher concentrations, twitch tension remained elevated for 5-10 min or more after wash-out of the peptide. When the peptides were presented as mixtures predicted by their stoichiometric ratios in the dFMRFamide propeptide, the effects were additive, and there were no detectable higher-order interactions among them. One peptide was tested and found to enhance synaptic transmission. At 0.1 microM, DPKQDFMRFamide increased the amplitude of the excitatory junctional current to 151% of baseline within 3 min. Together, these results indicate that the products of the Drosophila FMRFamide gene function as neurohormones to modulate the strength of contraction at the larval neuromuscular junction. In this role these seven peptides appear to be functionally redundant.

Identification and characterization of a myomodulin-like peptide in the leech

A novel myomodulin-like peptide, GMGALRLamide, has been purified and sequenced from extracts of 1000 medicinal leech nerve cords. Synthetic leech myomodulin-like peptide blocked the specific staining pattern of leech ganglia by the antiserum against Aplysia myomodulin A PMGMLRLamide. Moreover, the synthetic leech myomodulin-like peptide GMGALRLamide showed identical neuronal modulation effect on the giant leech Retzius cell compare to that by the synthetic Aplysia myomodulin A PMGMLRLamide.

Characterization of myomodulin-related peptides from the pulmonate snail Helix aspersa

Three myomodulin-related peptides--pQLSMLRLamide, PMSMLRLamide, and SLGMLRLamide--have been purified and sequenced from extracts of whole snails. The level of immunoreactive myomodulin was shown by HPLC and RIA to be widely distributed among 26 different snail tissues, with the highest levels (higher even than those in the central ganglia) occurring in certain male reproductive organs. Synthetic pQLSMLRLamide modified either the spontaneous rhythmic activity or the resting tone of several isolated muscular organs: the aorta, ventricle, upper gut, epiphallus, flagellum, and spermatheca; but the retractor muscles of the pharynx, penis, and tentacle were unaffected.

Myomodulin gene of Lymnaea: structure, expression, and analysis of neuropeptides

The myomodulin family of neuropeptides is an important group of neural cotransmitters in molluscs and is known to be present in the neural network that controls feeding behavior in the snail Lymnaea. Here we show that a single gene encodes five structurally similar forms of myomodulin: GLQMLRLamide, QIPMLRLamide, SMSMLRLamide, SLSMLRLamide, and PMSMLRLamide, the latter being present in nine copies. Analysis of the organization of the gene indicates that it is transcribed as a single spliced transcript from an upstream promoter region that contains multiple cAMP-responsive elements, as well as putative elements with homology to tissue-specific promoter-binding sites. The presence in nervous tissue of two of the peptides, GLQMLRLamide and PMSMLRLamide, is confirmed by mass spectrometry. In situ hybridization analysis indicates that the gene is expressed in specific cells in all ganglia of the CNS of Lymnaea, which will allow physiological analysis of the function of myomodulins at the level of single identified neurons.

Synthesis and expression of genes encoding putative insect neuropeptide precursors in tobacco

Neuropeptides are the key molecules in a multiplicity of physiological processes and their use in pest control has recently been suggested. Most neuropeptides are produced in the form of a precursor that is cleaved by proteolysis to yield various biologically active peptides. To mimic this structure, a method has been developed for synthesizing genes that code for putative polyneuropeptide precursors. As a model neuropeptide, the 5-amino-acid proctolin, one of the best studied invertebrate neuropeptides, functioning both as a visceral and a skeletal neuromuscular transmitter, was chosen. The synthetic gene was introduced into bacteria and tobacco plants, where it was efficiently transcribed. We present our results as a possible approach for the expression, in a variety of organisms, of synthetic genes coding for a wide repertoire of insect neuropeptides.

Processing of the L5-67 precursor peptide and characterization of LUQIN in the LUQ neurons of Aplysia californica

Metabolic labeling of the dorsal Left Upper Quadrant (LUQ) cells of the abdominal ganglion of Aplysia californica and RP-HPLC separation of their peptide content allowed us to identify the L5-67 precursor and its processed peptides. Cleavage of the signal peptide occurred between amino acids 23 and 24 of the prepropeptide and generated a propeptide of 89 amino acids. Further processing by endopeptidases at the twin basic residues Lys12-Arg13 of the precursor generated a peptide of 76 amino acids, as well as an amidated decapeptide, LUQIN. The sequence of LUQIN was determined by amino acid sequencing and by its comigration with the synthetic peptide Ala-Pro-Ser-Trp-Arg-Pro-Gln-Gly-Arg-Phe-amide in three different RP-HPLC systems. The amidation of LUQIN was further demonstrated by its resistance to carboxypeptidase A digestion.

Neural control of feeding

Substantial progress has been made in identifying the possible signals for initiating and terminating the appetitive aspects of feeding behavior in vertebrates. Strong evidence now implicates ATP (or an ATP-like molecule) and a fall in glucose in initiating feeding. In invertebrates, particular progress has been made in defining the nature and mechanisms of action of the neurotransmitters and peptide co-transmitters that regulate the consummatory aspects of feeding, and a number of new research tools for modelling the operation of simple feeding motor program networks have been developed.

Neuropeptides myomodulin, small cardioactive peptide, and buccalin in the central nervous system of Lymnaea stagnalis: purification, immunoreactivity, and artifacts

The neuropeptides myomodulin, small cardioactive peptide (SCP), and buccalin are widely distributed in the phylum Mollusca and have important physiological functions. Here, we describe the detailed distribution of each class of peptide in the central nervous system (CNS) of the snail Lymnaea stagnalis by the use of immunocytochemical techniques combined with dye-marking of electrophysiologically identified neurons. We report the isolation and structural characterization of a Lymnaea myomodulin, PMSMLRLamide, identical to myomodulin A of Aplysia californica. Myomodulin immunoreactivity was localized in all 11 ganglia, in their connectives, and in peripheral nerves. In many cases, myomodulin immunoreactivity appeared localized in neuronal clusters expressing FMRFamide-like peptides, but also in a large number of additional neurons. Double-labelling experiments demonstrated myomodulin immunoreactivity in the visceral white interneuron, involved in regulation of cardiorespiration. SCP-like immunoreactivity also appeared in all ganglia, and double-labelling experiments revealed that in many locations it was specifically associated with clusters expressing distinct exons of the FMRFamide gene that are differentially expressed in the CNS. Characterization of the two types of SCP-antisera used in this study, however, suggested that they cross-reacted with both FMRFamide and N-terminally extended FMRFamide-like peptides. Selective preadsorption with these cross-reacting peptides resulted in elimination of the widespread staining and retention of bona fide SCP immunoreactivity in the buccal and pedal ganglia only. Buccalin immunoreactivity was limited to the buccal and pedal ganglia. It did not coincide with the distribution of either myomodulin or SCP. Most immunoreactive clusters were found in the pedal ganglia.

Functional roles of peptide cotransmitters at neuromuscular synapses in Aplysia

Neuromuscular synapses in Aplysia have been used as model systems to study peptidergic cotransmission. Here we describe neuromuscular preparations in which it has been possible to investigate the physiological consequences of peptide transmitter release in detail. In the first preparation, the release of peptide cotransmitters from identified motor neuron B15 has been shown to be sensitive to the pattern of stimulation. High frequencies and long burst durations evoke peptide release that modulates muscle contractions in a manner similar to that produced by exogenous cotransmitter. By contrast, the release of the same peptide transmitters from motor neuron B1 show little dependence on pattern. We conclude that there are no stimulation patterns that are prerequisites for peptide release. Peptide cotransmitter release from motor neuron B47 has also been studied. B47, depending on the stimulation pattern, uses either ACh, which acts as a conventional inhibitory transmitter, or ACh plus neuropeptides, which act as excitatory modulatory cotransmitters. Thus, neuropeptide cotransmitters have the capability to greatly increase synaptic plasticity at neuromuscular synapses.