We have used immunocytochemical techniques to investigate the distribution of serotonin-like immunoreactivity in the nematode Ascaris suum. Antisera raised against serotonin (5-hydroxytryptamine, 5-HT) conjugated to bovine serum albumin (BSA) labelled a pair of neurons in the pharynx of both sexes and five cells in the ventral cord of the male tail. The labelling was blocked by 5-HT or by 5-HT conjugated to BSA. The 5-HT-immunoreactive cells in the pharynx resemble neurosecretory cells and are probably homologous to the neurosecretory motor neurons (NSM) in Caenorhabditis elegans; the cells in the male tail appear to be motor neurons that are homologous to CP neurons in C. elegans. Other cells that stain with 5-HT antisera have been observed in C. elegans but are not seen in Ascaris.
The site and mode of action of serotonin on locomotion were investigated in the parasitic nematode Ascaris suum. Injection of serotonin into Ascaris immediately caused paralysis in animals that were generating locomotory waveforms. Injected serotonin also increased body length and decreased the number of propagating body waves. Similar injections into the male tail produced a ventral tail curl. Injection of N-acetyl-serotonin had no effect on the generation of locomotory waveforms, but increased the body length and decreased the number of body waves in the waveform. Other biogenic amines were also tested but were much less potent. Serotonin decreased the amplitude of a submaximal acetylcholine-induced muscle contraction and increased the time to attain this contraction. The time course of this effect on the response to ACh was much slower than the action of injected serotonin on locomotory waveforms, suggesting that additional elements are involved in the action of serotonin on locomotory behavior. Serotonin abolished spontaneous slow potentials in VI motor neurons and decreased the frequency of EPSPs in DE2 motor neurons, probably by a pre-synaptic mechanism. In the male tail, serotonin depolarized the male-specific transverse ventral muscle cells, but did not affect either dorsal or ventral longitudinal muscle cells.
Recent technical advances have rapidly advanced the discovery of novel peptides, as well as the transcripts that encode them, in the parasitic nematode Ascaris suum. Here we report that many of these novel peptides produce profound and varied effects on locomotory behavior and levels of cyclic nucleotides in A. suum. We investigated the effects of 31 endogenous neuropeptides encoded by transcripts afp-1, afp-2, afp-4, afp-6, afp-7, and afp-9 - 14, (afp: Ascaris FMRFamide –like Precursor protein) on cyclic nucleotide levels, body length and locomotory behavior. Worms were induced to generate anteriorly propagating waveforms, peptides were injected into the pseudocoelomic cavity, and changes in the specific activity (nmol/mg protein) of second messengers cAMP (3′5′ cyclic adenosine monophosphate) and cGMP (3′5′ cyclic guanosine monophosphate) were determined. Many of these neuropeptides changed the levels of cAMP (both increases and decreases were found), whereas few neuropeptides changed the level of cGMP. A subset of the peptides that lowered cAMP was investigated for effects on the locomotory waveform and on body length. Injection of AF19, or AF34 (afp-13), AF9 (afp-14), AF26 or AF41 (afp-11) caused immediate paralysis and cessation of propagating body waveforms. These neuropeptides also significantly increased body length. In contrast, injection of AF15 (afp-9) reduced the body length, and decreased the amplitude of waves in the body waveform. AF30 (afp-10) produced worms with tight ventral coils. Although injection of neuropeptides encoded by afp-1 (AF3, AF4, AF10 or AF13) produced an increased number of exaggerated body waves, there were no effects on either cAMP or cGMP. By injecting peptides into behaving A. suum, we have provided an initial screen of the effects of novel peptides on several behavioral and biochemical parameters.
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