W.P.M. Geraerts

A glia-derived acetylcholine-binding protein that modulates synaptic transmission

There is accumulating evidence that glial cells actively modulate neuronal synaptic transmission. We identified a glia-derived soluble acetylcholine-binding protein (AChBP), which is a naturally occurring analogue of the ligand-binding domains of the nicotinic acetylcholine receptors (nAChRs). Like the nAChRs, it assembles into a homopentamer with ligand-binding characteristics that are typical for a nicotinic receptor; unlike the nAChRs, however, it lacks the domains to form a transmembrane ion channel. Presynaptic release of acetylcholine induces the secretion of AChBP through the glial secretory pathway. We describe a molecular and cellular mechanism by which glial cells release AChBP in the synaptic cleft, and propose a model for how they actively regulate cholinergic transmission between neurons in the central nervous system.

Rapid Communication: Neuropeptide Expression and Processing as Revealed by Direct Matrix-Assisted Laser Desorption Ionization Mass Spectrometry of Single Neurons

Abstract: Neuropeptides were directly detected in single identified neurons and the neurohemal area of peptidergic (neuroendocrine) systems in the Lymnaea brain by using matrix‐assisted laser desorption ionization mass spectrometry (MALDI‐MS). The samples were placed in matrix solution and ruptured to allow mixing of cell contents with the matrix solution. After formation of matrix crystals, the analytes were analyzed by MALDI‐MS. It was surprising that clean mass spectra were produced, displaying extreme sensitivity of detection. In one of the neuroendocrine systems studied, we could demonstrate for the first time, by comparing the peptide patterns of soma and of neurohemal axon terminals, that processing of the complex prohormone expressed in this system occurs entirely in the soma. In the other system studied, novel peptides could be detected in addition to peptides previously identified by conventional molecular biological and peptide chemical methods. Thus, complex peptide processing and expression patterns could be predicted that were not detected in earlier studies using conventional methods. As the first MALDI‐ MS study of direct peptide fingerprinting in the single neuron these experients demonstrate that MALDI‐MS forms a new and valuable approach to the study of the synthesis and expression of bioactive peptides, with potential application to single‐cell studies in vertebrates, including humans.

Towards Understanding the Role of Insulin in the Brain: Lessons from Insulin-related Signaling Systems in the Invertebrate Brain

Insulin is a molecule that has played a key role in several of the most important landmarks in medical and biological research. It is one of the most extensively studied protein hormones, and its structure and function have been elucidated in many vertebrate species, ranging from man to hagfish and turkey. The structure, function as well as tissue of synthesis of vertebrate insulins are strictly conserved. The structural identification of insulin-related peptides from invertebrates has disrupted the picture of an evolutionary stable peptide hormone. Insulin-related peptides in molluscs and insects turned out to be a structurally diverse group encoded by large multi-gene families that are uniquely expressed in the brain and serve functions different from vertebrate insulin. In this review, we discuss invertebrate insulins in detail. We examine how these peptides relate to the model role that vertebrate insulin has played over the years; however, more importantly, we discuss several unique principles that can be learned from them. We show how diversity of these peptides is generated at the genetic level and how the structural diversity of the peptides is linked to the exclusive presence of a single type of neuronal insulin receptor-related receptor. We also discuss the fact that the invertebrate peptides, in addition to a hormonal role, may also act in a synaptic and/or nonsynaptic fashion as transmitters/neuromodulators on neurons in the brain. It can be expected that the use of well-defined neuronal preparations in invertebrates may lead to a further understanding of these novel functions and may act as guide preparations for a possible role of insulin and its relatives in the vertebrate brain.

The sorLA cytoplasmic domain interacts with GGA1 and -2 and defines minimum requirements for GGA binding

We report that the Vps10p domain receptor sorLA binds the adaptor proteins GGA1 and ‐2, which take part in Golgi–endosome sorting. The GGAs bind with differential requirements via three critical residues in the C‐terminal segment of the sorLA cytoplasmic tail. Unlike in sortilin and the mannose 6‐phosphate receptors, the GGA‐binding segment in sorLA contains neither an acidic cluster nor a dileucine. Our results support the concept of sorLA as a potential sorting receptor and suggest that key residues in sorLA and sortilin conform to a new type of motif (Ψ–Ψ–X–X–∅) defining minimum requirements for GGA binding to cytoplasmic receptor domains.

Early evolutionary origin of the neurotrophin receptor family

Neurotrophins and their Trk receptors play a crucial role in the development and maintenance of the vertebrate nervous system, but to date no component of this signalling system has been found in invertebrates. We describe a molluscan Trk receptor, designated Ltrk, from the snail Lymnaea stagnalis. The full‐length sequence of Ltrk reveals most of the characteristics typical of Trk receptors, including highly conserved transmembrane and intracellular tyrosine kinase domains, and a typical extracellular domain of leucine‐rich motifs flanked by cysteine clusters. In addition, Ltrk has a unique N‐terminal extension and lacks immunoglobulin‐like domains. Ltrk is expressed during development in a stage‐specific manner, and also in the adult, where its expression is confined to the central nervous system and its associated endocrine tissues. Ltrk has the highest sequence identity with the TrkC mammalian receptor and, when exogenously expressed in fibroblasts or COS cells, binds human NT‐3, but not NGF or BDNF, with an affinity of 2.5 nM. These findings support an early evolutionary origin of the Trk family as neuronal receptor tyrosine kinases and suggest that Trk signalling mechanisms may be highly conserved between vertebrates and invertebrates.

The brain of Lymnaea contains a family of FMRFamide-like peptides

Authentic FMRFamide and two FMRFamide-related heptapeptides were purified from the central nervous system of the fresh water snail Lymnaea stagnalis. The sequences of the heptapeptides were determined as: Ser-Asp-Pro-Phe-Leu-Arg-Phe-NH2 (SDPFLRFamide) and Gly-Asp-Pro-Phe-Leu-Arg-Phe-NH2 (GDPFLRFamide) by modified Edman degradation and enzymatic digestion. Relatively high quantities of the deamidated and therefore non-immunoreactive analogs of these two peptides (SDPFLRF and GDPFLRF) were also found. SDPFLRFamide and GDPFLRFamide were synthesized and were found to be chromatographically and biologically indistinguishable from the natural peptides, confirming the sequences. The log dose-response curves for the chronotropic action of either synthetic peptide on the heart of Lymnaea was very similar to that of FMRFamide. These data indicate that Lymnaea contains a family of FMRFamide-like peptides.

A NOVEL G PROTEIN-COUPLED RECEPTOR MEDIATING BOTH VASOPRESSIN- AND OXYTOCIN-LIKE FUNCTIONS OF LYS-CONOPRESSIN IN LYMNAEA STAGNALIS

We have cloned a receptor, named LSCPR, for vasopressin-related Lys-conopressin in Lymnaea stagnalis. Lys-conopressin evokes Ca(2+)-dependent Cl- currents in Xenopus oocytes injected with LSCPR cRNA. Expression of LSCPR mRNA was detected in central neurons and peripheral muscles associated with reproduction. Upon application of Lys-conopressin, both neurons and muscle cells depolarize owing to an enhancement of voltage-dependent Ca2+ currents and start firing action potentials. Some neurons coexpress LSCPR and Lys-conopressin, suggesting an autotransmitter-like function for this peptide. Lys-conopressin also induces a depolarizing response in LSCPR-expressing neuroendocrine cells that control carbohydrate metabolism. Thus, in addition to oxytocin-like reproductive functions, LSCPR mediates vasopressin-like metabolic functions of Lys-conopressin as well.

CRNF, a Molluscan Neurotrophic Factor That Interacts with the p75 Neurotrophin Receptor

A 13.1-kilodalton protein, cysteine-rich neurotrophic factor (CRNF), was purified from the mollusk Lymnaea stagnalis by use of a binding assay on the p75 neurotrophin receptor. CRNF bound to p75 with nanomolar affinity but was not similar in sequence to neurotrophins or any other known gene product. CRNF messenger RNA expression was highest in adult foot subepithelial cells; in the central nervous system, expression was regulated by lesion. The factor evoked neurite outgrowth and modulated calcium currents in pedal motor neurons. Thus, CRNF may be involved in target-derived trophic support for motor neurons and could represent the prototype of another family of p75 ligands.

Expression and characterization of molluscan insulin-related peptide VII from the molluscLymnaea stagnalis

A complementary DNA clone encoding molluscan insulin-related peptide VII was identified from a complementary DNA library of the cerebral ganglia of the CNS of the freshwater snail, Lymnaea stagnalis. The novel molluscan insulin-related peptide VII complementary DNA encodes a preprohormone resembling the organization of preproinsulin, with a putative signal sequence, and an A and B chain, and is connected by an unusual long C peptide. The A and B chains, as well as the C peptide of molluscan insulin-related peptide VII, differ remarkably in primary structure with the previously identified molluscan insulin-related peptides. The C peptide of molluscan insulin-related peptide VII shares no significant sequence identity with counterparts in other molluscan insulin-related peptides. Both molluscan insulin-related peptide VII and the other molluscan insulin-related peptides exhibit structural features which make them a unique class of the insulin superfamily. Molluscan insulin-related peptide VII complementary DNA was shown to hybridize in situ with messenger RNA present in the cerebral light green cells, neuroendocrine cells that control growth and that have previously been shown to produce molluscan insulin-related peptides I-III and V. Uniquely, the molluscan insulin-related peptide VII gene is also expressed in neurons that may form part of the feeding circuitry in Lymnaea, indicating that it may function as a neurotransmitter/neuromodulator.

Molecular cloning and characterization of an invertebrate homologue of a neuropeptide Y receptor

Neuropeptide Y is an abundant and physiologically important peptide in vertebrates having effects on food intake, sexual behaviour, blood pressure and circadian rhythms. Neuropeptide Y homologues have been found in invertebrates, where they are very likely to play similar, important roles. Although five neuropeptide Y‐receptor subtypes have been identified in mammals, none has been reported from invertebrates. Here we describe the cloning of a neuropeptide Y‐receptor from the brain of the snail Lymnaea stagnalis. The identity of the receptor was deduced by expressing the neuropeptide Y‐receptor‐encoding cDNA in Chinese Hamster Ovary cells, which were subsequently challenged with size‐fractionated Lymnaea brain extracts. An active peptide, selected on the basis of its ability to induce changes in cAMP levels, was purified to homogeneity, analysed by mass spectrometry and amino acid sequence determination, and turned out to be a Lymnaea homologue of neuropeptide Y.