Evolution of arthropod visual systems: Development of the eyes and central visual pathways in the horseshoe crab<i>Limulus polyphemus</i>Linnaeus, 1758 (Chelicerata, Xiphosura)

Harzsch, Steffen; Vilpoux, Kathia; Blackburn, David C.; Platchetzki, David; Brown, Nadean L.; Melzer, Roland R.; Kempler, K; Battelle, Barbara‐Anne

doi:10.1002/dvdy.20866

Cited by 71 publications

(28 citation statements)

References 85 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Many publications and modern glossaries confuse eyes of visual systems, as defined above, with light sensitive channels subtending lenses, but which do not supply retinotopic neuropils. The lenses of Onychophora (Strausfeld et al, 2006), the paired median lenses of xiphosurans , single lenslets of Chilopoda , and the lenses of Chelicerata, including Pycnogonida, all supply light to photoreceptor neurons that connect to retinotopic neurons comprising discrete visual neuropils belonging to the protocerebral neuromere of the brain (Strausfeld et al, 2006;Harzsch et al, 2006;Strausfeld, 2012;Lehmann et al, 2012;Lehmann and Melzer, 2013). In contrast, the nauplius eyes of crustaceans and the ocelli of insects, their likely homologues, supply sparse outputs to distributed areas in the central protocerebrum but not to specialized visual neuropils (N€ assel and Hagberg, 1985;Lacalli, 2009;Fritsch and Richter, 2010).…”

Section: Introductionmentioning

confidence: 99%

Arthropod eyes: The early Cambrian fossil record and divergent evolution of visual systems

Strausfeld

Edgecombe

et al. 2016

Arthropod Structure & Development

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 99%

Arthropod eyes: The early Cambrian fossil record and divergent evolution of visual systems

Strausfeld

Edgecombe

et al. 2016

Arthropod Structure & Development

View full text Add to dashboard Cite

“…Deeper knowledge of, e.g., R-cell projections and visual neuropil architecture is missing, hence there is no stable basis on which to compare visual system features among pycnogonids and to those of their putative arthropod outgroups. In Chelicerata other than Pycnogonida, the visual systems of Limulus polyphemus [15],[16],[17] and Cupiennius salei [18],[19], which are important model organisms in the field of visual neuroscience, are especially well studied. In scorpions the only study of the visual neuropils is that of Hanström [13].…”

Section: Introductionmentioning

confidence: 99%

Wiring a Periscope – Ocelli, Retinula Axons, Visual Neuropils and the Ancestrality of Sea Spiders

2012

View full text Add to dashboard Cite

The Pycnogonida or sea spiders are cryptic, eight-legged arthropods with four median ocelli in a ‘periscope’ or eye tubercle. In older attempts at reconstructing phylogeny they were Arthropoda incertae sedis, but recent molecular trees placed them as the sister group either to all other euchelicerates or even to all euarthropods. Thus, pycnogonids are among the oldest extant arthropods and hold a key position for the understanding of arthropod evolution. This has stimulated studies of new sets of characters conductive to cladistic analyses, e.g. of the chelifores and of the hox gene expression pattern. In contrast knowledge of the architecture of the visual system is cursory. A few studies have analysed the ocelli and the uncommon “pseudoinverted” retinula cells. Moreover, analyses of visual neuropils are still at the stage of Hanström's early comprehensive works. We have therefore used various techniques to analyse the visual fibre pathways and the structure of their interrelated neuropils in several species. We found that pycnogonid ocelli are innervated to first and second visual neuropils in close vicinity to an unpaired midline neuropil, i.e. possibly the arcuate body, in a way very similar to ancestral euarthropods like Euperipatoides rowelli (Onychophora) and Limulus polyphemus (Xiphosura). This supports the ancestrality of pycnogonids and sheds light on what eyes in the pycnogonid ground plan might have ‘looked’ like. Recently it was suggested that arthropod eyes originated from simple ocelli similar to larval eyes. Hence, pycnogonid eyes would be one of the early offshoots among the wealth of more sophisticated arthropod eyes.

show abstract

“…2) (Regier et al 2005;Friedrich and Tautz 1995;Hwang et al 2001;Strausfeld 1998). Some myriapod and chelicerate species carry compound eyes as well, but these exhibit less similarity than is observed between insects and crustaceans (Harzsch et al 2007;Harzsch et al 2006). Informatively, of the two synonyms for the super-clade constituting crustaceans and insects, Pancrustacea and Tetraconata, the latter refers to the presence of four cone cells in the ommatidia of insect and crustacean species (Shultz and Regier 2000;Dohle 2001).…”

Section: Ancient Heritagementioning

confidence: 99%

Evolution of Insect Eyes: Tales of Ancient Heritage, Deconstruction, Reconstruction, Remodeling, and Recycling

Buschbeck

Friedrich

2008

Evo Edu Outreach

View full text Add to dashboard Cite

The visual organs of insects are known for their impressive evolutionary conservation. Compound eyes built from ommatidia with four cone cells are now accepted to date back to the last common ancestor of insects and crustaceans. In species as different as fruit flies and tadpole shrimps, the stepwise cellular patterning steps of the early compound eye exhibit detailed similarities implying 500 million years of developmental conservation. Strikingly, there is also a cryptic diversity of insect visual organs, which gives proof to evolution's versatility in molding even the most tenacious structures into something new. We explore this fascinating aspect in regard to the structure and function of a variety of different insect eyes. This includes work on the unique compound-single-chamber combination eye of twistedwinged insects and the bizarre evolutionary trajectories of specialized larval eyes in endopterygote insects.

show abstract

Evolution of arthropod visual systems: Development of the eyes and central visual pathways in the horseshoe crabLimulus polyphemusLinnaeus, 1758 (Chelicerata, Xiphosura)

Cited by 71 publications

References 85 publications

Arthropod eyes: The early Cambrian fossil record and divergent evolution of visual systems

Arthropod eyes: The early Cambrian fossil record and divergent evolution of visual systems

Wiring a Periscope – Ocelli, Retinula Axons, Visual Neuropils and the Ancestrality of Sea Spiders

Evolution of Insect Eyes: Tales of Ancient Heritage, Deconstruction, Reconstruction, Remodeling, and Recycling

Contact Info

Product

Resources

About