Comparative aspects of invertebrate neuropeptides.

1. We searched for bioactive peptides, most of which were considered to be neuropeptides, in various animals of several phyla. These peptides were compared with each other and with peptides identified by many other investigators. Consequently, we found that structures of neuropeptides are generally conserved in each phylum. 2. We also found some exceptional interesting aspects. First, there are a number of peptide groups whose members are distributed among several phyla. Second, there are many structural similarities between molluscan and annelidan peptides as if molluscs and annelids were the animals in a phylum. Third, certain toxic peptides of invertebrates are closely related to vertebrate neuropeptides. 3. In addition to the above phylogenetic aspects, we found some other interesting aspects. A wide structural variety of members of a peptide group is generally found in invertebrate species. Invertebrate muscles seem to be generally regulated not only by some or several classical non-peptidic neuromediators but also by various peptidic neuromediators. Peptides containing a D-amino acid residue are not rare.

Cardioactive peptides isolated from the brain of a Japanese octopus, Octopus minor.

Octopus cardioactive peptides (Ocp-1: Gly-D-Phe-Gly-Asp, and Ocp-3: Gly-Ser-Trp-Asp) were isolated from brain extracts of the octopus, Octopus minor, using the isolated systemic heart as a bioassay. These peptides showed both positive chronotropic and inotropic effects on the heart. The stereoisomers at position 2 were also isolated, but their activities were only 1/10(3)-1/10(4) those of the corresponding isomers. The presence of the peptides in the systemic heart was confirmed by time-of-flight mass spectrometry (MS) and tandem MS analysis. The results suggested that Ocp-1 and Ocp-3 might be involved in excitatory control of the octopus cardiovascular system as neuropeptides and/or neurohormones.

Peptides controlling stifness of connective tissue in sea cucumbers.

We present the first evidence of a system of four bioactive peptides that affect the stiffness of sea cucumber dermis. The body wall dermis of sea cucumbers consists of catch connective tissue that is characterized by quick and drastic stiffness changes under nervous control. The peptides were isolated from the body wall, their amino acid sequences determined, and identical peptides synthesized. Two peptides, which we named holokinins, are homologous with bradykinin. We tested the effect of the peptides on the mechanical properties of sea cucumber dermis. Both of the holokinins softened the dermis, and a pentapeptide that we designated as NGIWYamide stiffened it. Both effects were reversibly suppressed by anesthesia with menthol. We called the fourth peptide stichopin; it had no direct effect on the stiffness of the dermis but suppressed action of the neurotransmitter acetylcholine reversibly. The results suggest that the peptides are neuropeptides and are part of a sophisticated system of neurotransmitters and neuromodulators that controls the connective tissue stiffness of sea cucumber dermis.