Effect of modafinil on electroretinograms of Lycosa tarentula in relation visual circadian rhythm (Araneae, Lycosidae)

Injections of modafinil, a drug able to induce in vertebrates an awakening effect via an effective central alpha 1-adrenergic tone, induce modifications of the amplitude and latency of electroretinograms (ERGs) in the spider Lycosa tarentula, during dark adaptation. Results of experiments are different from one eye type to another as circadian activity rhythms of the retinae also differ. Modafinil induces a decrease of diurnal amplitudes and has no effect on nocturnal amplitudes of ERGs of anterior-lateral eyes; in the case of posterior-median eyes, the amplitudes are increased in daytime as well as at night. Prazosin, antagonist of alpha 1-adrenergic receptors, injected after modafinil, induces a decrease of the amplitudes of ERGs in the same eyes. These results are discussed in relation to the visual activity of this species, both diurnal and nocturnal. The concepts of waking state versus sleep are not precisely characterized in arachnids, so that the effects of modafinil on L. tarentula may not be considered like those described in vertebrates.     

Appearance of ocular electrical responses during development of cavernicolous and epigaeic opilionids (Arachnida)

The appearance of the electroretinogram was established during the development of two species of opilionids, an epigaeic species, Pachylus chilensis, and a cavernicolous one, Ischyropsalis luteipes. In nymphs and adults of the two species, electroretinograms of about the same amplitude can be recorded. During embryonic and larval development they are quite different. In Ischyropsalis luteipes, it is impossible to record an electrical response before hatching. In Pachylus chilensis on the other hand an initial inconstant and very small response occurs from the 50th hour of development of the retina and can always be recorded from the 72nd hour. In older embryos, the response has a progressively greater amplitude, but remains a simple negative wave. On the tenth day, when the first synaptic relays appear, the electroretinogram takes the shape of that of the adult. Given that transmission electronic microscopy cannot detect differences between the microvilli of these two species, it is tempting to compare Ischyropsalis luteipes lack of response with that of the mutant norp A of Drosophila melanogaster in which transmission electron microscopy shows no marked difference, whereas freeze-etching shows a very low number of intramembranous particles.     

Circadian Structural Changes in the Retina of Lycosa tarentula (Araneae: Lycosidae)

Daily structural changes of the rhabdoms are described in the four eye types of a lycosid spider submitted to laboratory conditions: LD 12:12 (light on at 08.00, 100 lux). From a study of animals submitted to constant darkness during fourteen days, rhabdom turnover was shown to be circadian. Each type of retina exhibits its own rhythmic turnover of rhabdoms. Anterior-lateral, posterior-median and lateral eyes are mostly diurnal; anterior-median retinae comprise 300 receptors with mainly nocturnal functioning and 150 receptors with mainly diurnal functioning. A correlation was found between rhythms of locomotor activity, other activity, and rhabdom turnover in L. tarentula suggesting that the same pacemaker controls these different rhythms.     

Circadian Structural Changes in the Retina of Lycosa tarentula (Araneae: Lycosidae)

Daily structural changes of the rhabdoms are described in the four eye types of a lycosid spider submitted to laboratory conditions: LD 12:12 (light on at 08.00, 100 lux). From a study of animals submitted to constant darkness during fourteen days, rhabdom turnover was shown to be circadian. Each type of retina exhibits its own rhythmic turnover of rhabdoms. Anterior-lateral, posterior-median and lateral eyes are mostly diurnal; anterior-median retinae comprise 300 receptors with mainly nocturnal functioning and 150 receptors with mainly diurnal functioning. A correlation was found between rhythms of locomotor activity, other activity, and rhabdom turnover in L. tarentula suggesting that the same pacemaker controls these different rhythms.