Your search keyword '"Scyphozoa ultrastructure"' showing total 2 results

1. Nerves in the endodermal canals of hydromedusae and their role in swimming inhibition.

Author

Mackie GO and Meech RW

Subjects

Animals, Electrophysiology, Endoderm ultrastructure, Immunohistochemistry, Microscopy, Electron, Transmission, Muscles physiology, Muscles ultrastructure, Scyphozoa ultrastructure, Endoderm innervation, Muscles innervation, Nervous System Physiological Phenomena, Scyphozoa physiology, Swimming physiology

Abstract

N eoturris breviconis (Anthomedusae) has a nerve plexus in the walls of its endodermal canals. The plexus is distinct from the ectodermal nerve plexuses supplying the radial and circular muscles in the ectoderm and no connections have been observed between them. Stimulation of the endodermal plexus evokes electrical events recorded extracellularly as "E" potentials. These propagate through all areas where the plexus has been shown by immunohistology to exist and nowhere else. When Neoturris is ingesting food, trains of "E" potentials propagate down the radial canals to the margin and cause inhibition of swimming. This response is distinct from the inhibition of swimming associated with contractions of the radial muscles but both may play a part in feeding and involve chemoreceptors. Preliminary observations suggest that the "E" system occurs in other medusae including Aglantha digitale (Trachymedusae) where the conduction pathway was previously thought to be an excitable epithelium.

Published

2008

2. Gap and septate junctions in the excitable endoderm of Polyorchis penicillatus (Hydrozoa, Anthomedusae).

Author

King MG and Spencer AN

Subjects

Action Potentials, Animals, Intercellular Junctions ultrastructure, Microscopy, Electron, Scyphozoa physiology, Cnidaria ultrastructure, Endoderm ultrastructure, Scyphozoa ultrastructure

Abstract

The morphological basis of impulse conduction in a jellyfish epithelium was investigated. Lanthanum impregnation of endodermal canal and endodermal lamella verified the existence of true gap junctions in Polyorchis. In both transverse and en face sections of gap junctions, electron-lucent globules, with a width of 7--8 nm and a spacing of about 11 nm, are evident. Gap-junctions are concentrated at the peripheral canal margin and septate junctions are localized around the canal lumen. Epithelial cells of the endodermal canals are capable of conducting a non-decrementing action potential. It is suggested that endodermal spike propagation, which can mediate 'crumpling' behaviour, is dependent upon low-resistence ionic pathways provided by gap-junctions and upon sealing of the intercellular space from saline extracellular fluids by septate junctions.

Published

1979