Journal ArticleDOI
Development and differentiation of the eye in Platynereis dumerilii (Annelida, Polychaeta)
TLDR
The nereid polychaete, Platynereis dumerilii, possess two pairs of post‐trochophoral eyes with one vitreous body each and the rate of eye development and differentiation varies.Abstract:
The nereid polychaete, Platynereis dumerilii, possess two pairs of post-trochophoral eyes with one vitreous body each. The development of these eyes has first been observed in 2-day-old larvae. Whether the eye anlagen arise from stem cells or from undifferentiated ectodermal tissue was not determined. At first, the anlagen of the anterior and the posterior eyes adjoin each other. They separate in late 3-day-old larvae. The first separated eye complexes consist each of two supporting and two sensory cells. The supporting cells synthesize two different kinds of granules, the pigment granules of the pigment cup and the prospective tubules of the vitreous body. These tubules accumulate in the distal process of the supporting cell. The vitreous body is formed by compartments of the supporting cells filled with the osmiophilic vitreous body tubules. The short, bulbar photosensory processes bear microvilli that emerge into the ocular cavity. At the apex of each sensory cell process, a single cilium (or occasionally two) arises. The sensory cells contain a different kind of pigment granule within their necks at the level of the pigment cup. The rate of eye development and differentiation varies. New supporting cells are added to the rim of the eye cup. They contribute to the periphery of the vitreous body like onion skins, and sensory cells move between supporting cells. The older the individual compartments of the vitreous body are, the more densely packed is their content of vitreous body tubules. Elongation of the sensory and supporting cell processes of the older cells increases the volume of the eye. The eyespots of the trochophore are briefly described as of the two-celled rhabdomeric type with a single basal body with ciliary rootlet.read more
Citations
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Journal ArticleDOI
Mechanism of phototaxis in marine zooplankton
Gáspár Jékely,Julien Colombelli,Harald Hausen,Keren Guy,Ernst H. K. Stelzer,François Nédélec,Detlev Arendt +6 more
TL;DR: The results provide the first mechanistic understanding of phototaxis in a marine zooplankton larva and show how simple eyespots regulate it, and propose that the underlying direct coupling of light sensing and ciliary locomotor control was a principal feature of the proto-eye and an important landmark in the evolution of animal eyes.
Journal ArticleDOI
Development of pigment-cup eyes in the polychaete Platynereis dumerilii and evolutionary conservation of larval eyes in Bilateria
Detlev Arendt,Kristin Tessmar,Maria-Ines Medeiros de Campos-Baptista,Adriaan Dorresteijn,Joachim Wittbrodt +4 more
TL;DR: Analysis of expression of conserved eye specification genes in the early development of larval and adult pigment-cup eyes in Platynereis dumerilii indicates that polychaete six1/2 expression outlines the entire visual system from early developmental stages onwards and ath-positive clusters generate the first photoreceptor cells to appear.
Journal ArticleDOI
Reconstructing the eyes of Urbilateria.
Detlev Arendt,Joachim Wittbrodt +1 more
TL;DR: A comparison supports homology of cerebral eyes in Protostomia; it challenges, however,homology of chordate and non-chordate cerebral eyes that employ photoreceptor cells with non-orthologous phototransductory cascades.
Journal ArticleDOI
The normal development of Platynereis dumerilii (Nereididae, Annelida)
TL;DR: A staging ontology representing the comprehensive list of developmental stages of P. dumerilii normal development is provided and an overview of important steps in the development of the nervous system and of the musculature is provided using fluorescent labeling techniques and confocal laser-scanning microscopy.
Journal ArticleDOI
Trochophora larvae: cell-lineages, ciliary bands, and body regions. 1. Annelida and Mollusca.
TL;DR: The trochophora concept and the literature on cleavage patterns and differentiation of ectodermal structures in annelids ("polychaetes") and molluscs are reviewed, showing conspicuous similarities between the early development of the two phyla, related to the highly conserved spiral cleavage pattern.
References
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Journal ArticleDOI
Further observations on the fine structure of some invertebrate eyes.
TL;DR: Electron microscopy reveals the lens in the eye of nereid annelids to be composed of highly folded, interdigitating processes of the pigment cells of the retina.
Journal ArticleDOI
[The eye of Platynereis dumerilii (Polychaeta): its fine structure in ontogenetic and adaptive change].
Fischer A,Brökelmann J +1 more
TL;DR: The pupillar region of light and dark-adapted specimens was examined and the kinetics of pupilar movements are discussed.
Journal ArticleDOI
The fine structure of the lens and photoreceptors of Nereis virens.
D. A. Dorsett,R. Hyde +1 more
TL;DR: Attention is drawn to the evolutionary parallel between the shadow reflex of Branchiomma and the “off” responses of the photoreceptors in the distal retina of Pecten, both animals being exceptional within their phyla in having photoreCEPTors of the ciliary type.
Fine structure of the eyes of an alciopid polychaete, Vanadis tagensis (Annelida)
TL;DR: The fine structure of the pair of large and complex cerebral ocelli of Vanadis tagensis is described and these eyes are compared to the descriptions of the cerebral o celli of cephalopods, onychophorans, and phyllodocidan polychaetes.
Journal ArticleDOI
Presumptive photoreceptor structures of the trochophore of Harmothoë imbricata (Polychaeta)
P. L. Holborow,M. S. Laverack +1 more
TL;DR: In the late trochophore (14 days old) an organ of different origin and formation but of presumed photoreceptor type begins to develop among nerve cell bodies below the apex of the animal.