The taxon Cycloneuralia includes Nematoda, Nematomorpha, Priapulida, Kinorhyncha and Loricifera. The name-giving autapomorphy of this taxon is the so-called cycloneuralian brain. In this type of brain the neuropil forms a ring around the anterior intestinal system, while the somata of the brain nerve cells form clusters anterior and posterior of this ring neuropil. In the ventral region of the brain, a paired or unpaired ventral nerve cord arises. Further longitudinal neurites or neurite bundles, as well as entire or partial circular neurites connecting the longitudinal ones, are present in most taxa. This can be interpreted as a remnant of an orthogonal pattern in the trunk region. In nematodes, the nervous system is postulated to express little variation throughout the taxon, but there is an extreme heterogeneity in the intensity, with which nervous systems are known. For the ‘model nematode’ Caenorhabditis elegans, each single neuron is known, while data especially from free-living nematodes are lacking. Available data support nematodes having a comparable general architecture of the nervous system, but some variation in detail. Nematomorphs show the greatest differences in the nervous system, probably due to their parasitic mode of life during most of the life cycle. Although available data do not correspond with any one particular shape of the brain, it certainly does not form a ring of equal thickness and is therefore not cycloneuralian. Scalidophora (Priapulida, Kinorhyncha, Loricifera) have a cycloneuralian brain and correspond in the innervation of the scalids representing cuticular structures on the introvert that include receptor cells.
A generic character of the genus Spiophanes (Annelida, Sedentaria: Spionidae) is the presence of parapodial glandular organs. Parapodial glandular organs in Spiophanes species include secretory cells with cup-shaped microvilli, similar to those present in deep-sea inhabiting vestimentiferans and frenulate Siboglinidae. These cells are supposed to secrete β-chitin for tube-building. In this study, transverse histological and/or ultrathin sections of parapodial glandular organs and tubes of Spiophanes spp. as well as of Glandulospio orestes (Spionidae) and Owenia fusiformis (Oweniidae) were examined. Fluorescent markers together with confocal laser scanning microscopy, and Raman spectroscopy were used to detect chitin in the parapodial glandular organs of Spiophanes and/or in the glands of Owenia and Glandulospio. Tubes of these taxa were tested for chitin to elucidate the use of it for tube-building. The examinations revealed a distinct labelling of the gland contents. Raman spectroscopy documented the presence of β-chitin in both gland types of Spiophanes. The tubes of Spiophanes were found to have a grid-like structure that seems to be built with this β-chitin. Tests of tubes of Dipolydora quadrilobata (Spionidae) for chitin were negative. However, the results of our study provide strong evidence that Spiophanes species, O. fusiformis and probably also G. orestes produce chitin and supposedly use it for tube-building. This implies that the production of chitin and its use as a constituent part of tube-building is more widespread among polychaetes as yet known. The histochemical data presented in this study support previous assumptions inferring homology of parapodial glandular organs of Spionidae and Siboglinidae based on ultrastructure. Furthermore, transmission electron microscopy-based evidence of secretory cells with nail-headed microvilli in O. fusiformis suggests homology of parapodial grandular organs across annelids including Sipuncula.
The Nematomorpha (horsehair worms) and Nematoda (round worms) are sister taxa (together Nematoida) and closely related to Scalidophora (Priapulida, Kinorhyncha, Loricifera). To date, all species were assumed to possess a specific brain type, i.e., the "cycloneuralian" brain that forms a ring-shaped neuropil around the pharynx and is composed of anteriorly and posteriorly located somata. However, descriptions of the nematomorph nervous system are rare and somewhat variable, calling in to question the validity of the cycloneuralian condition. To clarify whether there is a typical cycloneuralian pattern in the nematomorph brain, we investigated the anterior end of Gordius aquaticus with different methods: histology, immunohistochemistry and micro-CT analysis. Three-dimensional reconstructions were made from histological serial sections. The brain is composed of a central neuropil and a ring-shaped structure with associated somata. The unpaired ventral nerve cord emerges from the posteroventral part of the brain. A pharynx/esophagus is absent. In addition to the brain, a peripheral nerve plexus was detected. In summary, we interpret the architecture of the brain as potentially derived from a cycloneuralian structure, but being highly modified. The central position of the neuropil is possibly a consequence of the reduction of the anterior intestinal system as a result of the parasitic lifestyle. The ring-shaped arrangement of the somata may be a remnant of a cycloneuralian arrangement, after the two rings of somata (= cycloneuralian condition) either fused or one ring was reduced to form one massive ring-shaped structure in G. aquaticus. J. Morphol. 278:106-118, 2017. ©© 2016 Wiley Periodicals,Inc.
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