Excitatory synaptogenesis between identified Lymnaea neurons requires extrinsic trophic factors and is mediated by receptor tyrosine kinases.

Neurotrophic factors have well established roles in neuronal development and adult synaptic plasticity, but their precise role in synapse formation has yet to be determined. This paper provides the first direct evidence that neurotrophic factors in brain conditioned medium (CM) differentially regulate excitatory and inhibitory synapse formation. Somata of identified presynaptic and postsynaptic neurons were isolated from the CNS of Lymnaea and were cultured in a soma-soma configuration in the presence (CM) or absence [defined medium (DM)] of trophic factors. In DM, excitatory synapses did not form. When they were paired in CM or in DM containing Lymnaea epidermal growth factor (EGF); however, all presynaptic neurons reestablished their specific excitatory synapses, which had electrical properties similar to those seen in vivo. CM-induced formation of excitatory synapses required transcription and de novo protein synthesis, as indicated by the observations that synapse formation was blocked by the protein synthesis inhibitor anisomycin and the protein transcription blocker actinomycin D; the CM factor was inactivated by boiling. They were also blocked by receptor tyrosine kinase inhibitors (lavendustin A, genistein, K252a, and KT5926) but not by inactive analogs (genistin and lavendustin B), suggesting that the effect was mediated by receptor tyrosine kinases. These results, together with our previously published data, demonstrate that trophic factors are required for excitatory, but not inhibitory, synapse formation and extends the role of EGF from cell proliferation, neurite outgrowth, and survival to excitatory synapse formation.

Differential regulation of epidermal growth factor and transforming growth factor-alpha messenger ribonucleic acid in the rat anterior pituitary and hypothalamus induced by stresses.

Evidence has shown that epidermal growth factor (EGF) and transforming growth factor-alpha (TGF alpha) are present in the anterior pituitary as well as the hypothalamus, and that EGF can influence the function of pituitary cells, particularly corticotropes in vivo and in vitro. However, little is known about their exact functional roles and how they are regulated in these two areas. The present study was designed to determine if EGF and TGF alpha messenger RNA (mRNA) are expressed in the rat anterior pituitary and hypothalamus and how stress conditions such as cold, ether, or restraint affect their local expression. A sensitive mRNA detection method, the ribonuclease protection assay, detected both EGF and TGF alpha mRNA in the rat anterior pituitary and hypothalamus. Reverse transcription-polymerase chain reaction (RT-PCR) further showed the presence of EGF and TGF alpha mRNA in these two areas and several other rat tissues (submandibular gland, liver, kidney, lung cerebral cortex, and testis). No TGF alpha mRNA was found in the kidney, however. EGF mRNA was up-regulated in the anterior pituitary after 30 min acute cold stress (CS) and restrainer-restraint stress (RS) but not 30 min after ether stress (2 min, ES), novelty stress (NS), or tape-restraint stress (TS). Further analysis showed that EGF mRNA expression decreased after 1 h CS (1C) and then increased after 3 h CS (3C). In contrast, TGF alpha mRNA in the anterior pituitary and hypothalamus and hypothalamic EGF mRNA did not show significant changes in response to either acute stresses (CS, ES, RS, TS, NS) or longer CS (1C, 3C). Our results suggest that 1) EGF, is up-regulated after some stresses; 2) increased pituitary EGF mRNA in response to stresses varies with the type of stress; and 3) pituitary TGF alpha and hypothalamic EGF and TGF alpha may be not involved in the stress response.

Characterization of Aplysia carboxypeptidase E.

Carboxypeptidase E (CPE) is involved in the biosynthesis of peptide hormones and neurotransmitters. To determine whether a recently reported Aplysia californica cDNA encodes a CPE-like enzyme, this cDNA was expressed in the baculovirus system. The Aplysia CPE is optimal at pH 5.5-6.5 and is inhibited by chelating agents and by the sulfhydryl reagent p-chloromercuriphenyl sulfonate. The effect of divalent cations and active site-directed inhibitors on enzyme activity are generally similar for Aplysia and rat CPE. Western blot analysis using antisera to the N- and C-terminal regions of the Aplysia CPE show that the Aplysia CPE is present in atrial glands and ovotestis. This Aplysia CPE is purified on a p-aminobenzoyl-Arg Sepharose affinity column under conditions that selectively purify rat CPE. Taken together, these results suggest that the previously cloned cDNA represents a CPE-like enzyme that is expressed in Aplysia tissue.

Structural characterization of a Lymnaea putative endoprotease related to human furin.

A number of peptides have been identified in the central nervous system of the freshwater snail, Lymnaea stagnalis, that function as hormones and neurotransmitters/neuromodulators. These peptides are typically proteolytically processed from larger prohormones mostly at sites composed of single or multiple basic amino acid residues. Previously we demonstrated a diversity of putative prohormone convertases that may be involved in prohormone processing in the Lymnaea brain. In the present report, we have characterized a cDNA clone encoding a putative endoprotease of 837 amino acids. The primary structure of endoprotease (Lfur2) was comparable to that of human furin and contained a putative catalytic domain, a Cys-rich domain, and a transmembrane region. The catalytic domain of Lfur2 demonstrated about 70% residue identity when compared with human furin, PACE4 and Drosophila Dfur1 and dKLIP-1. The Lfur2 gene was expressed in the central nervous system as well as various peripheral tissues of Lymnaea.

Localization of immunoreactive alpha-bag-cell peptide in the central nervous system of Aplysia.

The bag cells of the marine mollusc Aplysia are well-characterized neuroendocrine cells that initiate egg laying, but the natural stimulus triggering bag-cell activity has not been determined. As a first step toward identifying central neurons that might provide synaptic or neurohormonal input onto the bag-cell network, antibodies specific for alpha-bag-cell peptide (alpha-BCP) were generated. This peptide belongs to a small family of structurally related peptides that can elicit bag-cell activity in vitro. Antibody specificity was established by immunodot assay and preabsorption studies: immunocytochemical labeling was abolished in each ganglion when the antibodies were preincubated with either alpha-BCP-thyroglobulin conjugate or alpha-BCP-(1-8) but was not affected by preincubation with thyroglobulin or thyroglobulin-thyroglobulin conjugate. The antibodies specifically labeled the bag cells in the abdominal ganglion and ectopic bag cells in both the abdominal and right pleural ganglia. The ectopic bag cells were similar to conventional bag cells in size and morphology, but varied in number and location among preparations. In the cerebral ganglion, the antibodies labeled a bilaterally symmetrical pair of cell clusters, containing approximately ten cells each, on the dorsal surface of the ganglion. The cerebral cells were smaller than bag cells, were constant in location, and sent their processes into the neuropil rather than the connective tissue sheath. Immunoreactive processes were observed in the neuropils of the cerebral, pleural, and pedal ganglia and among the axons of the cerebropedal, cerebropleural, and pleurovisceral connectives. No immunoreactive cell bodies were observed in the buccal or pedal ganglia. Identical patterns of labeling were observed in Aplysia californica, A. brasiliana, and A. dactylomela. The distribution of immunoreactive cell bodies within the circumesophageal ganglia of all three species thus parallels the distribution of receptive sites for the in vitro induction of bag-cell activity by atrial gland peptide B, a peptide structurally related to alpha-BCP. These observations suggest that the immunoreactive cells identified in these studies, or a subset of them, may be involved in the physiological induction of bag-cell activity. Since low doses of alpha-BCP have additional inhibitory actions on the bag cells, however, it is possible that the identified cells could play a more complex role in the regulation of bag-cell activity.

Molecular cloning of a cDNA encoding the neuropeptides APGWamide and cerebral peptide 1: localization of APGWamide-like immunoreactivity in the central nervous system and male reproductive organs of Aplysia.

While much is known about the neural and endocrine mechanisms that control egg laying in the gastropod mollusk Aplysia, relatively little is known about the regulation of male reproductive activity in this simultaneous hermaphrodite. In the present study, we have cloned and sequenced a cDNA that encodes a precursor protein, the predicted posttranslational processing of which presumably generates nine copies of the neuropeptide Ala-Pro-Gly-Trp-NH2 (APGWamide), five connecting peptide sequences, and a C-terminal peptide. The sequence of one connecting peptide is identical to the previously characterized cerebral peptide 1. Northern blot analysis identified two major APGWamide mRNA transcripts (approximately 1.3 kb, approximately 2.4 kb), which were present in central nervous system ganglia, but were most abundant in the right cerebral and right pedal ganglia. Immunohistochemical studies using sexually mature Aplysia demonstrated that the vast majority of APGWamide-like immunoreactivity was localized in 30-40 neurons along the anterior and medial margins of the right cerebral ganglion and in a cluster of 15-20 neurons in the right pedal ganglion. A total of only about ten immunoreactive neurons were located in other ganglia. Immunohistochemistry also demonstrated that APGWamide was present in the reproductive organs that participate in the storage or transport of sperm, including the small hermaphroditic duct (site of sperm storage before mating), the white hemiduct (also known as the copulatory duct), and penial complex. As a group, these data suggest that APGWamide may play a role in regulating male reproductive function in Aplysia, as it does in other gastropods.

Mollusk-derived growth factor and the new subfamily of adenosine deaminase-related growth factors.

Peptide and protein growth factors play critical roles in the control of proliferation, differentiation and survival of most, if not all, cell types. In this review, we describe a newly isolated growth factor from Aplysia californica, mollusk derived growth factor (MDGF), that is a member of the adenosine deaminase-related growth factor (ADGF) subfamily. Other known subfamily members from a range of invertebrate and vertebrate species include: insect-derived growth factor, Drosophila ADGFs, tsetse salivary growth factors, insect adenosine deaminases (ADAs; Lutzomyia, Culex, Aedes, Anopheles), and cat eye syndrome critical region gene 1 (CECR1) in humans, pigs, and zebrafish. ADGFs from vertebrates and invertebrates contain both an ADA domain and a novel N-terminal region of about 100 amino acids. Catalytic residues involved in ADA activity are conserved in ADGFs, and inhibitors of ADA can block ADGF activity. ADA enzymatic activity has been shown, by inhibitor and site-directed mutagenesis studies, to be related to the ability of ADGFs from many species to stimulate cell proliferation. The available evidence suggests that the conversion of adenosine to inosine (or their analogs) is important for the mitogenic actions of ADGFs. Future investigations of this novel subfamily should lead to the identification of their receptors.

Lymnaea EGF and gigantoxin I, novel invertebrate members of the epidermal growth factor family.

In this review, we compare the sequence and structural relationships of two epidermal growth factor (EGF) family related proteins that have recently been discovered in invertebrate species. The first is L-EGF, a secreted growth factor from the gastropod mollusk Lymnaea stagnalis. The second is a peptide toxin (Gigantoxin I), isolated from the sea anenome Stichodactyla giganteus, which can paralyze crabs. L-EGF and Gigantoxin I share striking sequence similarity with mammalian erbB1 receptor ligands, including most of the essential receptor binding sites. Intriguingly, L-EGF's tertiary structure resembles more the structure of the EGF-like domain of coagulation factors. That is, the secondary and tertiary structure of L-EGF indicates the presence of a double-stranded beta-sheet but also suggests that this protein, in contrast to all other erbB1 ligands, contains a calcium-binding domain. One of the most remarkable features of L-EGF and Gigantoxin I however, is the indication that these protein are synthesized as non-membrane bound secreted peptides. This feature sets L-EGF and Gigantoxin I apart from all other members of the EGF family or EGF-like proteins identified thus far. We discuss sequence similarities and dissimilarities in the light of indications that, despite the more than 600 million years of phylogenetic distance separating both these invertebrates from mammals, Gigantoxin I and L-EGF retain some affinity for the mammalian erbB-family of receptors. Considering that mammalian EGF and its family members are frequently implicated in neoplastic diseases, the increasing number of identified and characterized invertebrate EGF family members may provide valuable leads in the design of erbB receptor antagonists.

Mollusk-derived growth factor: cloning and developmental expression in the central nervous system and reproductive tract of Aplysia.

We have isolated and characterized an atrial gland cDNA that corrects the previously reported sequence for Aplysia atrial gland granule-specific antigen (AGSA), a glycoprotein of unknown function. We designated the protein mollusk-derived growth factor (MDGF) to distinguish the revised sequence from AGSA and to emphasize its similarity to an insect-derived growth factor (IDGF). We describe MDGF mRNA expression that suggests a possible role during embryonic development and CNS injury repair.

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.

Molecular cloning of a cDNA encoding a potential water-borne pheromonal attractant released during Aplysia egg laying.

Recently deposited egg cordons are a source of water-borne pheromones that attract the marine mollusk Aplysia into breeding aggregations and coordinate male and female reproductive behavior within the aggregation. A potential pheromonal attractant has been isolated from egg cordon eluates and the peptide partially characterized [S.D. Painter, B. Clough, X. Fan, G.T. Nagle, Soc. Neurosci. Abstr., Vol. 22 (1996) 837]. Using this information, we have cloned an Aplysia albumen gland cDNA that encodes a precursor protein containing a single copy of the full-length peptide, and demonstrated that there are abundant levels of pheromone mRNA transcripts (0.8 and 2.5 kb) in the albumen gland. This is consistent with the reported function of the gland (i.e. packaging the eggs into a cordon for deposition), with behavioral studies showing that the albumen gland is a potential source of attractants, and more recent biochemical studies in which the full-length peptide has been isolated from the albumen gland. This is the first candidate peptide pheromone in mollusks and the first in invertebrates. The pheromonal regulatory system in Aplysia may provide a model system for examining the structural characteristics of peptide pheromones.

Molecular cloning of Aplysia neuronal cDNAs that encode carboxypeptidases related to mammalian prohormone processing enzymes.

The bag cell neurons of Aplysia synthesize an egg-laying hormone (ELH) precursor that initially is cleaved into two fragments in the Golgi apparatus, and the fragments are differentially packaged in separate granule populations and further processed. Aplysia Afurin, Afurin2, prohormone convertase 1 (PC1), and PC2 are thought to be involved in the posttranslational processing of the ELH prohormone. In the present study, we have cloned Aplysia neuronal cDNAs that encode an enzyme most closely related to mammalian carboxypeptidase E (CPE), a peptide hormone processing enzyme that removes basic residues during prohormone processing. Northern blot analysis identified a single Aplysia CPE mRNA (approximately 5.2 kb) in central nervous system tissue. The C-terminal region of Aplysia CPE contains amphiphilic alpha-helices that may serve as a hydrophobic membrane anchor. A novel neuronal Aplysia enzyme was also identified by the polymerase chain reaction that was most closely related to the carboxypeptidase D (CPD)-related duck protein gp180 and the Drosophila silver gene carboxypeptidases. Aplysia CPE and the CPD-related enzyme are candidate processing enzymes that may play a role in the processing of the ELH prohormone and other Aplysia prohormones.

Cloning and expression of Aplysia carboxypeptidase D, a candidate prohormone-processing enzyme.

Many peptide hormones in a variety of species are produced from larger precursors by limited proteolysis at basic amino acid-containing sites. The marine mollusc Aplysia has homologs of mammalian peptide-processing enzymes, including furin, prohormone convertase 1 (PC1), PC2, and carboxypeptidase E (CPE). A novel neuronal Aplysia enzyme was recently identified that was most closely related to carboxypeptidase D (CPD; Fan and Nagle, DNA Cell Biol. 15, 937-945, 1996), a second carboxypeptidase thought to be present in the secretory pathway and to contribute to peptide hormone processing. We have identified and cloned multiple overlapping bag-cell neuron cDNAs that encode two proteins that are members of the CPD family. Sequence analyses demonstrate that the longer CPD protein (1446 residues) contains an N-terminal signal peptide and four carboxypeptidase-like domains; the third and fourth domains are not predicted to form active enzymes, as several critical residues are absent. The shorter CPD protein is predicted to contain two active carboxypeptidase-like domains. Northern blot analysis identified a major Aplysia CPD mRNA (5.3 kb) and several smaller minor transcripts in central nervous system tissue. The CPD was purified from Aplysia ovotestis using a method previously developed for mammalian CPD. The purified Aplysia CPD binds antisera raised against regions of the protein encoded by the Aplysia cDNA clone, as well as an antiserum raised against duck CPD. The enzymatic properties of purified Aplysia CPD are generally similar to those of mammalian CPD. Aplysia CPD is a candidate prohormone-processing enzyme that may play a role in the processing of Aplysia prohormones in the secretory pathway.

Molecular cloning of prohormone convertase 1 from the atrial gland of Aplysia.

We have screened an Aplysia atrial gland cDNA library using a prohormone convertase (PC)1 probe prepared by polymerase chain reaction (PCR) and have isolated an Aplysia PC1-related full-length 3.6-kb cDNA clone. The cDNA sequence (3,565 bp) encoded a putative preproendoprotease (APC1) of 703 amino acid residues that showed considerable sequence identity with other eukaryotic PC1s, and indicated a high degree of sequence identity with an Aplysia nervous system PC sequence (aPC1B). Northern blot analysis of atrial gland RNA identified two APC1 transcripts of 3.9 kb and 5.0 kb. APC1 is a candidate PC that may play an important role in the processing of egg-laying hormone (ELH)-related precursors in atrial gland secretory cells and represents one of the first examples of PC1 expression in an exocrine tissue.

Molecular cloning, cDNA sequence, and localization of a prohormone convertase (PC2) from the Aplysia atrial gland.

Neuropeptides and peptide hormones are synthesized as part of larger precursor proteins that are processed post-translationally by subtilisin-related calcium-dependent prohormone convertases (PCs), frequently at multiple basic sites, to generate biologically active peptides. The atrial gland of Aplysia californica produces large quantities of egg-laying hormone (ELH)-related peptides, providing a unique opportunity to study prohormone processing. We have screened an Aplysia atrial gland cDNA library using a Lymnaea stagnalis PC2 probe and have isolated an Aplysia PC2-related 4.6-kb cDNA partial clone that was truncated on the 5' end. The remaining 5' atrial gland PC2 nucleotide sequence was obtained by reverse transcription/polymerase chain reaction (RT-PCR). The composite cDNA structure (5.6 kb) was deduced from sequence analysis of the RT-PCR product combined with the sequence obtained from the cDNA clone. The deduced cDNA of Aplysia atrial gland PC2 encoded a putative preproendoprotease of 653 amino acids that was evolutionarily related to other eukaryotic PC2s, and showed the strongest sequence identity with recently reported Aplysia nervous tissue PC2 sequences. In situ hybridization demonstrated extensive expression of PC2 in atrial gland secretory cells. The cDNA clone contained a relatively long 3'untranslated region (3'-UTR) of 3,632 nucleotides. Strikingly, the 3'-UTR also contained several major nucleotide repeat sequences including the microsatellite repeats, (CA)n and (TG)n, and a TA-rich region comprised largely of the triplet repeat (TTA)n. The characterized Aplysia PC2 is a candidate endoprotease that may play an important role in the processing of ELH-related precursors in the atrial gland and represents the first example of PC2 expression in exocrine tissue.

Molecular cloning and cellular localization of a furin-like prohormone convertase from the atrial gland of Aplysia.

Prohormone convertases (PCs) are Ca(2+)-dependent subtilisin-related endoproteases that have been implicated in the post-translational processing of prohormones and other proproteins. Furin is an ubiquitously expressed PC that has been shown to hydrolyze a wide variety of precursor proteins in secretory pathways. We have screened an Aplysia atrial gland cDNA library using a furin probe prepared by polymerase chain reaction (PCR) and have isolated an Aplysia furin-related 6.7-kb cDNA partial clone that was truncated on the 5' end. The remaining 5' atrial gland furin nucleotide sequence was obtained by two stages of reverse transcription PCR. The final composite nucleotide sequence of the atrial gland furin cDNA was 7,837 bp in length. This sequence encoded a putative preproendoprotease (Afurin2) of 824 amino acid residues that was related to other eukaryotic furins, and showed a high sequence identity with a recently reported Aplysia nervous system furin-like sequence. In situ hybridization demonstrated extensive expression of Afurin2 in atrial gland secretory cells. The cDNA clone contained a relatively long 3' untranslated region of 5,230 nucleotides that included a microsatellite repeat region (TG)n. The characterized Aplysia Afurin2 is a candidate PC that may play an important role in the processing of egg-laying hormone (ELH)-related precursors in the secretory cells of the atrial gland. In addition, comparative structural studies of Afurin2, together with previously reported localization studies, argue for the occurrence of a furin-like convertase within secretory granules.

Purification and characterization of Aplysia atrial gland secretory granules containing egg-laying prohormone-related peptides.

A purification scheme is described for the isolation of secretory granules containing egg-laying prohormone-related peptides from the atrial gland of Aplysia californica, an exocrine organ in the reproductive tract. Granules were purified by differential centrifugation of atrial gland homogenates followed by centrifugation on continuous Percoll-sucrose gradients. Quantitative enzyme assays in conjunction with electron microscopic analyses demonstrated that secretory granules thus isolated were significantly purified with respect to other subcellular organelles such as mitochondria and lysosomes. Immunoelectron microscopy demonstrated that the majority (approximately 85%) of the purified secretory granules were immunoreactive for A-NTP (N-terminal peptide), a cleavage product of the egg-laying prohormone-related A and A' precursors (residues 22-34). The purified granules represented an enriched source of peptides that were readily resolved by reversed-phase high performance liquid chromatography.

The bag cell egg-laying hormones of Aplysia brasiliana and Aplysia californica are identical.

Egg laying in the marine molluscan genus Aplysia is elicited by an egg-laying hormone (ELH) which induces ovulation and acts on central neurons to effect egg-laying behavior. ELH, isolated from the A. californica bag cells, and three ELH-related peptides, isolated from the A. californica atrial gland, have been chemically characterized, yet relatively little is known about homologous peptides in other Aplysia species. In these studies, the primary structure of A. brasiliana ELH was determined. Bag cell clusters were extracted in an acidic solution, and the peptides purified by sequential gel filtration and reversed-phase HPLC; ELH was identified by bioassay. Amino acid compositional and sequence analyses demonstrated that the neurohormone was a 36-residue peptide whose sequence was identical to that of A. californica ELH: NH2-Ile-Ser-Ile-Asn-Gln-Asp-Leu-Lys-Ala-Ile-Thr-Asp-Met-Leu-Leu-Thr-Glu- Gln-Ile- Arg-Glu-Arg-Gln-Arg-Tyr-Leu-Ala-Asp-Leu-Arg-Gln-Arg-Leu-Leu-Glu-Lys-COOH .

Aplysia brasiliana neurons R3-R14: primary structure of the myoactive histidine-rich basic peptide and its prohormone.

Neurons R3-R14 of the marine mollusc Aplysia are model neuroendocrine cells thought to regulate cardiovascular activity in vivo. The cells express a gene encoding three peptides--peptides I, II and the histidine-rich basic peptide (HRBP)--each of which has been chemically characterized in Aplysia californica. In the studies presented here, HRBP and its prohormone (proHRBP) were purified from A. brasiliana abdominal ganglion extracts by reversed-phase high-performance liquid chromatography and characterized by amino acid compositional and sequence analyses. ProHRBP was an 85-residue peptide whose sequence was: NH2-Glu-Glu-Val-Phe-Asp-Asp-Thr-Asp-Val-Gly-Asp-Glu-Leu-Thr-Asn-Ala-Leu- Glu-Ser - Val-Leu-Thr-Asp-Leu-Lys-Asp-Lys-Arg-Asp-Ala-Glu-Glu-Pro-Ser-Ala-Phe-Met- Thr-Arg - Leu-Arg-Arg-Gln-Val-Ala-Gln-Met-His-Ile-Trp-Arg-Ala-Asn-His-Asp-Arg-His- His-Ser - Thr-Gly-Ser-Gly-Arg-His-Ser-Arg-Phe-Leu-Thr-Arg-Asn-Arg-Tyr-Gly-Gly-Gly- His-Leu - Ser-Asp-Ala-COOG. It differed from A. californica pro-HRBP at seven of the 85 positions. Compositional and sequence analyses demonstrated that A. brasiliana HRBP was a 43-residue peptide corresponding to residues 43 through 85 of proHRBP, and that a significant proportion of the isolated peptide possessed a blocked NH2 terminus. Although this sequence differed from that of A. californica HRBP at five of 43 residues, the two peptides were approximately equipotent in inducing contractions of A. californica crop muscle in vitro, suggesting that the substituted residues may not be critical for biological activity.

Aplysia californica neurons R3-R14: primary structure of the myoactive histidine-rich basic peptide and peptide I.

The R3-R14 neurons of the marine mollusc Aplysia are neuroendocrine cells that express a gene encoding peptides I, II and histidine-rich basic peptide (HRBP), a myoactive peptide that excites Aplysia heart and enhances gut motility in vitro. Peptide II has been chemically characterized (35), but the complete primary structures of peptide I and HRBP have not been established by amino acid sequence analysis. HRBP, peptide I, and the prohormone (proHRBP) were therefore purified from acid extracts of Aplysia californica neural tissue using sequential gel filtration and reverse-phase high-performance liquid chromatography and chemically characterized. Amino acid sequence analysis demonstrated that HRBP was a 43-residue peptide whose sequence was: less than Glu-Val-Ala-Gln-Met-His-Val-Trp-Arg-Ala-Val-Asn-His-Asp-Arg-Asn-His-Gly- Thr-Gly - Ser-Gly-Arg-His-Gly-Arg-Phe-Leu-Ile-Arg-Asn-Arg-Tyr-Arg-Tyr-Gly-Gly-Gly- His-Leu - Ser-Asp-Ala-COOH. Compositional and sequence analyses of peptide I and proHRBP demonstrated that peptide I was a 26-residue peptide with the following sequence: NH2-Glu-Glu-Val-Phe-Asp-Asp-Thr-Asp-Val-Gly-Asp-Glu-Leu-Thr-Asn-Ala- Leu-Glu-Ser-Val-Leu-Thr-Asp-Phe-Lys-Asp-COOH. These results demonstrated that the pro-HRBP sequence predicted by nucleotide sequence analysis of a cDNA clone (24) was in fact synthesized in R3-R14 neurons. Hydrophilicity and hydrophobicity profiles of preproHRBP, combined with charge distribution profiles and predictive secondary structural analysis, showed that cleavage at dibasic sequences was strongly associated with peaks of hydrophilicity in alpha-helical regions of the preprohormone.