Neuropeptides: mediators of behavior in Aplysia

Atrial gland cells synthesize a family of peptides that can induce egg laying in Aplysia

Endogenous peptides induce egg laying in the marine mollusc Aplysia in two ways: egg-laying hormone (ELH) from the neuroendocrine bag cells acts directly, causing the release of eggs from the ovotestis; peptides A and B from the atrial gland act indirectly, activating the bag cells to release ELH. Another atrial gland peptide (egg-releasing hormone; ERH) is a structural and functional hybrid of ELH and peptides A and B; it can act both directly and indirectly to induce egg laying. Atrial glands were incubated in a mixture of 3H-amino acids for 18 h, and the biosynthetically labelled peptides isolated using sequential Sephadex G-50 column chromatography and isoelectric focusing. Radiolabelled peaks were localized and bioassayed in intact animals. Bioactive peaks were then characterized functionally using two additional assays: egg laying in bag cell-less animals (ELH-like peptides) and in vitro induction of bag cell discharge (A- and B-like peptides). ERH-like molecules are active in both assays. Homogeneity of bioactive IEF peaks was assessed by SDS-PAGE. Sephadex G-50 gel filtration of biosynthetically labelled atrial gland extracts reveals two major peptide peaks. Peak D (apparent Mr 6,000) is strongly radiolabelled and contains most of the egg-laying activity, but has a low absorbance at 274 nm. Peak E (apparent Mr 3,500) is weakly labelled and contains a small proportion of the total egg-laying activity, but has a large absorbance at 274 nm. Isoelectric focusing of radiolabelled peptides in peak D reveals seven distinct ELH-like species (pI 5.5, 7.5, 8.5, 8.7, 8.9, 9.1, 9.4), and two peaks (pI 5.9, 8.1) that have both ELH-like and A-/B-like activity. The pI 8.1 peak may result from the comigration of peptide A with ERH or with an unidentified ELH-like peptide. It is not yet clear whether the pI 5.9 activity results from comigration of distinct peptides or from the presence of a previously uncharacterized ERH-like molecule. Isoelectric focusing of radiolabelled peptides in peak E reveals five distinct ELH-like species (pI 7.3, 8.5, 8.7, 9.1, 9.4), and one peak (pI 8.9) with both ELH-like and A-/B-like activity. The pI 8.9 peak may result from the comigration of an ELH-like peptide with peptide B. Three of the ELH-like peptides (pI 8.5, 8.9, 9.1) found in peak E are probably identical to the ELH-like peptides found at the same pI's in peak D.(ABSTRACT TRUNCATED AT 400 WORDS)

Hybridization histochemistry

In this review we have used our own recent work as a flagship to illustrate the recent renaissance of interest in hybridization histochemistry. A trickle of papers followed the initial key excursion into the in situ labeling of tissue sections (48-50). Our own entry into this field started in 1978 and since then a confluence of important questions and technical advances has served to make hybridization histochemistry much more attractive as a research tool. Hybridization histochemistry is able to solve some problems for which there is no other suitable technique at this time. Hybridization histochemistry provides the location of anatomical sites of gene expression, and viral replication, with uniquely high specificity. We have taken 32P-labeled probes to what appears to be their limit of resolution, which is single cells in thin sections. While 32P has clear disadvantages, exposure time is relatively short and the use of fast-X-ray film to preview the results and estimate exposure time for emulsion has been turned to advantage. Our introduction (27) of the use of whole-mouse sections in hybridization histochemistry has great potential in hormonal, enzymatic, and growth factor gene expression and will no doubt prove of great use in developmental studies and examination of viral infection. The use of synthetic DNA (synthetic oligonucleotides) unshackles the technique from the need for an associated molecular biology laboratory and at once widens the horizon of application of the technique. Although hybridization histochemistry is a valuable research tool which will soon find a niche in many fields, in a short time it should become a key diagnostic aid. It may well become the method of preference for detection of the expression of oncogenes and other cancer-related genes and for viruses which for other reasons are difficult to detect.

Expression of the L11 neuropeptide gene in the Aplysia central nervous system

Neuron L11 in the abdominal ganglion of Aplysia californica is thought to be both cholinergic and peptidergic. In previous studies, we isolated a cDNA clone encoding the precursor for an L11 secreted protein(s) by differentially screening an abdominal ganglion cDNA library. We now report the isolation of genomic clones encoding the L11 cDNA sequences. Analysis of these clones reveals that the gene is present in a single copy per haploid genome. RNA blotting and cDNA cloning demonstrate that the L11 gene is expressed not only in the abdominal ganglion but in the head ganglia as well. To define the positions of cells expressing this gene and to follow their processes, we raised antibodies to synthetic peptides defined by the cDNA sequence. Histochemistry revealed about 100 neurons containing immunoreactive material. These cells arborize in the neuropil and are distributed throughout the central nervous system, representing about 0.5% of the Aplysia central neurons. In addition, cells in the abdominal ganglion send processes to the mantle floor at the base of the gill via the genital and branchial nerves. Our data suggest that this network of cells expresses the single L11 peptide gene.

Signal sequences. The limits of variation

Variations in length and composition of the charged N-terminal, central hydrophobic and polar C-terminal regions in a large sample of signal sequences have been mapped, both as a function of the overall length of the sequence, and in an absolute sense, i.e. various "extremes" have been sought. The results show subtle differences between eukaryotic and prokaryotic sequences, but the general impression of signal sequences as being highly variable is reinforced. Criteria for a "minimal" signal sequence are suggested and discussed.

FMRFamide- and gastrin/CCK-like peptides in birds

Antibodies to the molluscan neuropeptide, Phe-Met-Arg-Phe-NH2 (FMRFamide) react with material in extracts of chicken brain. One of the immunoreactive peptides has the sequence Leu-Pro-Leu-Arg-Phe-NH2 (LPLRFamide). We have now raised antibodies to LPLRFamide and used these to examine the distribution and molecular forms of LPLRFamide-like peptides in the chicken. Several forms can be distinguished on the basis of HPLC retention times. Concentrations are highest (200 pmol X g-1) in hypothalamus, and lowest (less than 10 pmol X g-1) in cerebellum, spinal cord and gut. There are two common residues in FMRFamide and gastrin/CCK related peptides (-Met-X-Phe-amide). However, LPLRFamide is readily distinguishable from avian CCK and gastrin. The latter, like the mammalian gastrins, is a relatively strong stimulant of acid, and a weak stimulant of pancreatic enzyme secretion, in the chicken. The physiological roles of the vertebrate peptides with FMRFamide and LPLRFamide immunoreactivity remain to be elucidated, although evidence is emerging to suggest that they might act as transmitters in CNS regions associated with the input of sensory information (dorsal spinal cord and nucleus tractus solitarius).

Low molecular weight proteins of Aplysia neurosecretory cells

The proteins of identified cells from the Aplysia californica central nervous system were labeled with radioactive amino acids and fractionated on SDS acrylamide gels containing 6 M urea. Most of the large cells contain prominent, cell-specific protein products in the molecular weight range between 3 and 30 KD. The molecular weights of the largest specific prevalent protein products are in good agreement with the predicted molecular weights of precursors as determined from an analysis of cDNA clones homologous to mRNA's specifically expressed in several of these neurons. Biologically active peptides have been found in many of these cells. These data, and other indirect evidence suggests that the synthesis of a large amount of a particular protein in this molecular weight range is indicative of the synthesis of a neurosecretory product. We conclude that most, if not all, large neurons in the Aplysia central nervous system are peptidergic.

In situ hybridization histochemistry with synthetic oligonucleotides: strategies and methods

In situ hybridization histochemistry is a useful method for localizing specific mRNA and studying the regulation of gene expression in an anatomical context. Previously, classical recombinant DNA and microbiological techniques have been required to identify and nick-translate the cloned DNAs necessary for in situ hybridization experiments. These requirements can be circumvented by the use of synthetic oligonucleotides complementary to the mRNA of interest. Compared to cloned cDNA probes, oligonucleotides are easy to manufacture, penetrate tissue much more easily, can be made to correspond to a sequence at any point in a known cDNA structure, and allow for the design of more precise controls for in situ studies. We describe a number of considerations in oligonucleotide probe design, including unique probe design from cDNA sequences and mixed probe design from protein primary structure data. The issues of species specificity, G-C content, probe length, tissue-specific mRNA expression, repeated sequences, non-coding region specific probes, and gene family homologies are discussed in an in situ hybridization context. Alternative strategies for mixed probe design are also considered. Information on the synthesis, purification, and sequence confirmation of oligonucleotides is then presented, followed by methods for labeling and using these probes for in situ hybridization histochemistry. The special considerations of specificity controls are addressed, including combined in situ hybridization histochemistry and immunocytochemistry, competition studies, the use of multiple hybridization probes, Tm studies, and Northern analysis of extracted RNA. The current and future directions of research with this technique are considered, with emphasis on the need to improve quantitation in order to facilitate the study of gene expression and regulation at the single cell level.

Biophysical studies of ion channels

Ionic channels, the integral membrane proteins responsible for the brain's electrical activity, have long been studied with standard electrophysiological and biochemical methods. Recently, however, newly developed electrical and molecular biological methods have been brought to bear on long-standing questions in neurobiology. Goals of current channel research include elucidating the primary amino acid sequence and three-dimensional structure of channel species; the mechanisms of synthesis, sorting, membrane insertion, and degradation; and aspects of function such as gating, ion permeation and selectivity, and regulation. The latest research combines the new biochemical and electrophysiological techniques to reveal relations between molecular structure and function.