The fine structure of the ocelli of Triatoma infestans (Hemiptera: Reduviidae)

The morphology and fine structure of the ocelli of Triatoma infestans have been analyzed by means of light and electron microscopy. The two dorsal ocelli of this species are located behind the compound eyes, looking dorsally and frontally. Externally, the ocelli are marked by the corneal lenses virtually spherical in form and limited internally by a cuticular apodeme. The lens focuses the incoming rays beyond the retina. A single layer of corneagen cells lies below the cuticular lens. The corneagen cells and photoreceptors are arranged in a cup-like fashion beneath the cuticular lens. A distal retinal zone comprises the rhabdoms, which are laterally connected in an hexagonal meshwork. A middle retinal zone comprises the receptor cell segment free of rhabdom, and a proximal zone their axons. In the middle zone, the oviform nuclei and spheroids are located. Screening pigment granules are present within the retinal cell. Spherical mitochondria are homogeneously distributed in the cytoplasm of the cell body. In the axonal zone, mitochondria are found in the peripheral region. Axons from receptor cells extend into the ocellar neuropile at the base of the ocelli, to synapse with second order neurons. The large axons of second order neurons are bundled by glial cells. The ocellar plexus exhibits a high diversity of synaptic unions (i.e. axo-dendritic, axo-axonic, dendro-axonic, and dendro-dendritic).     

Animal eyes: defending the coat of mail

The eyes on the backs of molluscs known as chitons are shadow and motion detectors, the lenses of which are made of birefringent aragonite. These provide a focus both in and out of water.     

昆虫单眼的结构和功能

大多数昆虫的视觉器官除了复眼外还有一些简单的小眼,称为单眼。昆虫成虫和半变态类若虫的单眼称为背单眼,位于头顶两复眼之间。背单眼在数目和结构上都有较大变化,但基本结构包括角膜晶体、一层角膜生成细胞(覆盖在角膜晶体上)、视网膜(由大约1000个感光细胞构成,视类群而不同)。背单眼对弱光比较敏感,但在图像感知方面的作用并不显著;它是一种“激发器官”,可以增加复眼的感知能力。全变态昆虫的幼虫既没有复眼也没有背单眼,但在其头部两侧有些类似复眼小眼的侧单眼。侧单眼的结构也与小眼相似,包括角膜,晶体和由一些视网膜细胞组成的视杆。侧单眼是完全变态类昆虫幼虫仅有的感光器官,与复眼一样,它们可以感知颜色、形状、距离等等。     

The fine structure of the dorsal ocelli in the male bibionid fly

The dorsal ocelli of bibionid flies, details of which have not previously been described, were examined in males of Dilophus febrilis. The three ocelli are combined within an elevated chitin capsule, in a medial position between the enlarged dorsal compound eyes. The biconvex lenses show a multiple layering of up to 150 regularly spaced, clear and dense cuticle zones (100 nm spacing) which probably provide some spectral filtering, suggested by in vivo observations with an epifluorescence microscope. The corneagenous cells and the retina with 100-200 photoreceptor cells are adjoined proximally. A distal retina zone comprises the rhabdoms, which are laterally connected in an hexagonal network. The rhabdoms are between 4 and 15 mum in length; they decrease gradually from the dorsal to the ventral retina region. A middle retina zone comprises the receptor somata, a proximal zone, their axons. Synaptic contacts between axons and interneuron dendrites, feedback synapses to axons, and axo-axonic synapses are found, showing varying pre-synaptic structures. A possible functional role of the ocelli is discussed.     

Photoreceptors of cubozoan jellyfish

The anatomically sophisticated visual system of the cubozoan jellyfish Carybdea marsupialis is described. Individual cubomedusae have eight complex eyes, each with a cornea, lens, and retina of ciliated photoreceptor cells, eight slit ocelli, and eight dimple ocelli. The photoreceptor cells of the complex eyes are bipolar and resemble vertebrate rod cells. Each photoreceptor has an outer cylindrical light-receptive segment that projects into a vitreous space that separates the lens and the retina, an inner segment rich in pigment granules, and a basal region housing the nucleus. The outer segment is a modified cilium with a 9 + 2 arrangement of microtubules plus stacks of membrane. These stacks of membrane form numerous discs that are oriented transversely to the long axis of the cell. The outer segment is connected to the inner segment by a slender stalk. The basal end of each photoreceptor forms an axon that projects into an underlying layer of interneurons. Each ocellus is composed of ciliated photoreceptor cells containing pigment granules. Rhodopsin-like and opsin-like proteins are found in the membrane stacks of the outer segments of the photoreceptors of the complex eyes. An ultraviolet-sensing opsin-like protein is present in the inner segments and basal regions of some of the photoreceptors of the complex eyes. Rhodopsin-like proteins are also detected in the photoreceptors of the slit ocelli. The cellular lens, composed of crystallin proteins, shows a paucity of organelles and a high concentration of homogeneous cytoplasm. Neurons expressing RFamide (Arg-Phe-amide) comprise a subset of interneurons found beneath the retinas of the complex eyes. RFamide-positive fibers extend from these neurons into the stalks of the rhopalia, eventually entering into the subumbrellar nerve ring. Vision may play a role in the navigation, feeding, and reproduction of the cubomedusae.     

Chitons’ apparent camouflage does not reduce predation by green crabs Carcinus maenas

Chitons are very common molluscs on European rocky shores. They are common prey of fish and crabs and often display several colour morphs within a given habitat. Predation is one of the potential mechanisms accounting for chiton colour polymorphism. The colour variation is considered to provide a camouflage protection through a match with the substratum surface typology. However, the effectiveness of chiton polymorphism as a predation defence requires further investigation. Previously we found a relationship between chiton colour morphs and substrate characteristics, with chitons most commonly found on substrates that were of similar colour to their shells. Here, we examined whether each morph displayed an active choice for matching the substratum. Next, we assessed if the predation success of the intertidal common crab Carcinus maenas varied significantly with the absence/presence of an apparent camouflage effect created between the chiton colour morph and the substratum type. The present study indicates that chiton colour morphs probably actively choose substratum types where they blend in. Carcinus maenas was able to prey on all Lepidochitona cinereus colour morphs, regardless of the substrate camouflage effect. Surprisingly, the predation frequency was higher on camouflaged chitons than on contrasting chitons. It was concluded that chiton camouflage is probably not a defence mechanism against predation by the crab C. maenas, and that chiton colour polymorphism is probably promoted by other, more visual predators.     

GROWTH OF LENS AND OCULAR ENVIRONMENT: ROLE OF NEURAL RETINA IN THE GROWTH OF MOUSE LENS AS REVEALED BY AN IMPLANTATION EXPERIMENT

The lens of 6-day-old normal mouse was implanted into the lentectomized eye of adult mouse to examine the effect of retina upon the growth of the implanted lens in vivo. The implanted lens grew normally and its transparency was kept for more than 5 months after implantation. The connection between the implanted lens and the ciliary part of the recipient iris was well established with the regeneration of zonular fibers from the recipient. In young lenses implanted reversely into adult eyes, the epithelial cells facing the retina elongated and a new epithelium was formed on the corneal side of the lens within 5 days. Young lenses implanted either in normal or reverse orientation into eyes from which the retina was previously removed did not grow. The cells of the original lens epithelium of these lenses were randomly accumulated beneath the posterior lens capsule, while the anterior portion of the implanted lenses became an epithelial structure without cell elongation. These results suggest that the growth of the implanted lens may be dependent on the retina of the adult eye.     

The mapping of visual space by dragonfly lateral ocelli

We study the extent to which the lateral ocelli of dragonflies are able to resolve and map spatial information, following the recent finding that the median ocellus is adapted for spatial resolution around the horizon. Physiological optics are investigated by the hanging-drop technique and related to morphology as determined by sectioning and three-dimensional reconstruction. L-neuron morphology and physiology are investigated by intracellular electrophysiology, white noise analysis and iontophoretic dye injection. The lateral ocellar lens consists of a strongly curved outer surface, and two distinct inner surfaces that separate the retina into dorsal and ventral components. The focal plane lies within the dorsal retina but proximal to the ventral retina. Three identified L-neurons innervate the dorsal retina and extend the one-dimensional mapping arrangement of median ocellar L-neurons, with fields of view that are directed at the horizon. One further L-neuron innervates the ventral retina and is adapted for wide-field intensity summation. In both median and lateral ocelli, a distinct subclass of descending L-neuron carries multi-sensory information via graded and regenerative potentials. Dragonfly ocelli are adapted for high sensitivity as well as a modicum of resolution, especially in elevation, suggesting a role for attitude stabilisation by localization of the horizon.     

Effects of exogenous FGF-1 treatment on regeneration of the lens and the neural retina in the newt, Notophthalmus viridescens

Experiments were designed to compare the effects of recombinant newt fibroblast growth factor-1 (rnFGF-1) and recombinant human glial growth factor (rhGGF) on lens and retina regeneration in the eyes of adult newts. Both eyes were retinectomized and lentectomized. Beginning 3 days after the operation, one eye was given either 0.1 microg of rnFGF-1 or 0.1 microg of rhGGF in 1 microl of phosphate-buffered saline (PBS) per injection, three per week. Contralateral operated eyes served as controls and were treated with PBS alone or were not injected. In eyes that were not injected, injected with PBS alone, or with PBS containing rhGGF, regeneration of both the retina and the lens proceeded normally as described in the literature. In these control eyes, the entire retinal pigmented epithelium (RPE) depigmented/dedifferentiated and a retina rudiment formed from which a new retina regenerated by the end of the experiment at day 41 post-operation. Likewise, only a small area of dorsal iris depigmented/dedifferentiated and formed a lens vesicle from which a lens subsequently regenerated. The vitreous remained relatively free of loose cells.In eyes given rnFGF-1, the RPE depigmented/dedifferentiated and formed what appeared to be a retina rudiment but a new retina did not regenerate. Instead, vesicles were seen associated with the retina rudiment. In eyes given rnFGF-1, both the dorsal iris and ventral iris depigmented/dedifferentiated and lens regeneration occurred but the new lenses had abnormal fiber cells and the lens epithelium was very thin or absent. In addition, ectopic lenses usually regenerated in rnFGF-1-treated eyes. An abundance of loose cells were present in the vitreous of rnFGF-1-treated eyes associated largely with the RPE and the dorsal and ventral irises.The results are consistent with the view that the timely expression of FGFs is involved in the depigmentation/dedifferentiation of the RPE and dorsal iris and is necessary for proper regeneration of the lens and neural retina. Continued presence of FGF results in continued and excessive dedifferentiation, resulting in the lack of retina regeneration and abnormal lens regeneration.     

The ocelli of arctiid moths: ultrastructure of the retina during light and dark adaptation

The ultrastructure of the dorsal ocelli of two arctiid moths (Arctia caja (A. caja) and Creatonotos transiens (C. transiens) was investigated. The two ocelli are positioned laterally on the vertex of the head posterior to the antennae, close to the dorsal margin of the compound eyes. The biconvex corneal lens is located at the apex of a cone-shaped cuticular elevation, which encapsulates the retina. The corneagenous cell layer and the cup-like retina with about 100-130 receptor cells in A. caja (70-90 receptor cells in C. transiens) are adjoined proximally. The retina is completely enclosed by the perineurium and thus separated from the corneagenous cells and the surrounding hemolymph. Irregularly shaped rhabdomeres, consisting of densely packed microvilli, are present in the distal region of the receptor cells. Up to three cells may form a rhabdom. Thus a loose network of photoreceptive structures over the whole retina results. A unique feature of these arctiid ocelli are photoreceptor vacuoles containing microvilli. The function of these organelles is unknown. The rhabdomeric arrangement within the light and dark adapted retina differs considerably. The ultrastructure of the rhabdomeres indicates an intense membrane turnover. However, changes in adaptation state are not accompanied by dramatic changes in the photoreceptive area of an ocellus.     

The organization of honeybee ocelli: Regional specializations and rhabdom arrangements

We have re-investigated the organization of ocelli in honeybee workers and drones. Ocellar lenses are divided into a dorsal and a ventral part by a cusp-shaped indentation. The retina is also divided, with a ventral retina looking skywards and a dorsal retina looking at the horizon. The focal plane of lenses lies behind the retina in lateral ocelli, but within the dorsal retina in the median ocellus of both workers and drones. Ventral retinula cells are ca. 25 μm long with dense screening pigments. Dorsal retinula cells are ca. 60 μm long with sparse pigmentation mainly restricted to their proximal parts. Pairs of retinula cells form flat, non-twisting rhabdom sheets with elongated, straight, rectangular cross-sections, on average 8.7 μm long and 1 μm wide. Honeybee ocellar rhabdoms have shorter and straighter cross-sections than those recently described in the night-active bee Megalopta genalis. Across the retina, rhabdoms form a fan-shaped pattern of orientations. In each ocellus, ventral and dorsal retinula cell axons project into two separate neuropils, converging on few large neurons in the dorsal, and on many small neurons in the ventral neuropil. The divided nature of the ocelli, together with the particular construction and arrangement of rhabdoms, suggest that ocelli are not only involved in attitude control, but might also provide skylight polarization compass information.     

Anisotropic imaging in the dragonfly median ocellus: a matched filter for horizon detection

It is suggested that the dragonfly median ocellus is specifically adapted to detect horizontally extended features rather than merely changes in overall intensity. Evidence is presented from the optics, tapetal reflections and retinal ultrastructure. The underfocused ocelli of adult insects are generally incapable of resolving images. However, in the dragonfly median ocellus the geometry of the lens indicates that some image detail is present at the retina in the vertical dimension. Details in the horizontal dimension are blurred by the strongly astigmatic lens. In the excised eye the image of a point source forms a horizontal streak at the level of the retina. Tapetal reflections from the intact eye show that the field of view is not circular as in most other insects but elliptical with the major axis horizontal, and that resolution in the vertical direction is better than in the horizontal. Measurements of tapetal reflections in locust ocelli confirm their visual fields are wide and circular and their optics strongly underfocused. The ultrastructure suggests adaptation for resolution, sensitivity and a high metabolic rate, with long, widely separated rhabdoms, retinulae cupped by reflecting pigment, abundant tracheoles and mitochondria, and convoluted, amplified retinula cell plasma membranes.     

Multifocal lenses compensate for chromatic defocus in vertebrate eyes

The focal length of the vertebrate eye is a function of wavelength, i.e. the eye suffers from longitudinal chromatic aberration. Chromatic defocus is a particularly severe problem in eyes with high light-gathering ability, since depth of field is small due to a pupillary opening that is large in relation to the focal length of the eye. Calculations show that in such eyes only a narrow spectral band of light can be in focus on the retina. For the major part of the visual spectrum, spatial resolution should be limited by the optics of the eye and far lower than the resolving power achievable by the retinal cone photoreceptor mosaic. To solve this problem, fishes with irises unresponsive to light have developed lenses with multiple focal lengths. Well-focused images are created at the wavelengths of maximum absorbance of all spectral cone types. Multifocal lenses also appear to be present in some terrestrial species. In eyes with mobile irises, multifocal lenses are correlated with pupil shapes that allow all zones of the lens, with different refractive powers, to participate in the imaging process, irrespective of the state of pupil constriction. Accepted: 6 November 1998     

Homology of the Lateral Eyes of Scorpiones: A Six-Ocellus Model

Scorpions possess two types of visual organs, the median and lateral eyes. Both eyes consist of simple ocelli with biconvex lenses that differ in structure and function. There is little variation in the number of median ocelli across the order. Except for a few troglomorphic species in which the median ocelli are absent, all scorpions possess a single pair. In contrast, the number of pairs of lateral ocelli varies from zero to five across Scorpiones and may vary within species. No attempt has been made to homologize lateral ocelli across the order, and their utility in scorpion systematics has been questioned, due to the variation in number. A recent study examined the number of lateral ocelli among various Asian Buthidae C.L. Koch, 1837 and proposed a “five-eye model” for the family. This model has not been examined more broadly within Buthidae, however, nor compared with the patterns of variation observed among other scorpion families. An eyespot, referred to as an accessory lateral eye, situated ventral or posteroventral to the lateral ocelli, has also been reported in some scorpions. Analysis of its structure suggests it serves a nonvisual function. We present the first comparative study of variation in the lateral ocelli across the order Scorpiones, based on examination of a broad range of exemplar species, representing all families, 160 genera (78%), 196 species (9%), and up to 12 individuals per species. We propose a six-ocellus model for Recent scorpions with four accessory ocelli observed in various taxa, homologize the individual ocelli, and correct erroneous counts in the recent literature. We also investigate the presence of the eyespot across scorpions and discover that it is more widespread than previously recognized. Future work should investigate the genetic and developmental mechanisms underlying the formation of the lateral ocelli to test the hypotheses proposed here.     

An ocellar "pupil" that does not change with light intensity, but with the insect age in Triatoma infestans

The simple eyes (ocelli) of recently emerged adult Triatoma infestans exhibit a narrow elongated "pupil", surrounded by a ring of brown-reddish pigment, the "iris". This pupil does not respond to changes in the illumination, but varies in size after the imaginal ecdysis. This change corresponds, internally, with the growth of the corneal lens and the associated retina up to an age of about 20 days. This has not been previously observed in an insect. The use of this characteristic for recognising young adults of this species is suggested.     

A Focus on the Optical Properties of the Regenerated Newt Lens

Lens regeneration studies in the adult newt suggest that molecular aspects of lens regeneration are complete within 5 weeks of lentectomy. However, very little is known about the optical properties of the regenerated lens. In an aquatic environment, the lens accounts for almost all of the refractive power of the eye, and thus, a fully functional lens is critical. We compared the optical properties of 9- and 26-week regenerated lenses in the red spotted newt, Notophthalmus viridescens, with the original lenses removed from the same eyes. At 9 weeks, the regenerated lenses are smaller than the original lenses and are histologically immature, with a lower density of lens proteins. The 9 week lenses have greater light transmission, but significantly reduced focal length and refractive index than the original lenses. This suggests that following 9 weeks of regeneration, the lenses have not recovered the functionality of the original lens. By 26 weeks, the transmission of light in the more mature lens is reduced, but the optical parameters of the lens have recovered enough to allow functional vision.     

Hornets Can Fly at Night without Obvious Adaptations of Eyes and Ocelli

Hornets, the largest social wasps, have a reputation of being facultatively nocturnal. Here we confirm flight activity of hornet workers in dim twilight. We studied the eyes and ocelli of European hornets (Vespa crabro) and common wasps (Vespula vulgaris) with the goal to find the optical and anatomical adaptations that enable them to fly in dim light. Adaptations described for obligately nocturnal hymenoptera such as the bees Xylocopa tranquebarica and Megalopta genalis and the wasp Apoica pallens include large ocelli and compound eyes with wide rhabdoms and large facet lenses. Interestingly, we did not find any such adaptations in hornet eyes or ocelli. On the contrary, their eyes are even less sensitive than those of the obligately diurnal common wasps. Therefore we conclude that hornets, like several facultatively nocturnal bee species such as Apis mellifera adansonii, A. dorsata and X. tenuiscapa are capable of seeing in dim light simply due to the large body and thus eye size. We propose that neural pooling strategies and behavioural adaptations precede anatomical adaptations in the eyes and ocelli when insects with apposition compound eyes turn to dim light activity.     

A distinct gradient of fouling occurs across shells of rare under-boulder chitons

It is recognised that more research is needed on ecology of rare intertidal invertebrates to understand their ecological functions and aid their conservation. An example is chitons which are specialists of under-boulder habitat. Little is known about their interactions with the environment or other species, including spirorbid tubeworms which can co-occur in great abundances. This study describes for the first time a distinct pattern of spirorbid-tube fouling across the surfaces of chiton shells, and a similar pattern involving black staining of chitons from anoxic conditions. Posterior valves had 2–5 times as much fouling compared to anterior valves. This may have been caused by forward movement of chitons abrading away the anterior fouling. But signs of wear on shells that are caused by abrasion were also measured, and these were homogenous across the shell surface, suggesting abrasion does not cause the fouling pattern. I found five individuals of Cryptoplax striata (Lamarck, 1819) which were stained black by anoxic iron monosulphides, and the stained area was more than 10 times greater on posteriors than anteriors. These patterns may provide clues about interactions of chitons with fouling species, or about the types of microhabitats where chitons predominantly position different parts of their bodies.     

MICROGROWTH BANDS IN CHITONS: EVIDENCE OF TIDAL PERIODICITY

Microgrowth bands of typical molluscan appearance were clearlyrevealed by the acetate film technique in the sutural laminaeof the large chitons, Amaurochiton glaucus, Sypharochiton pelliserpentis,Cryptoconchus porosus and Acanthopleura granulata. In all speciesthere was a cyclical pattern, averaging close to 28 bands percycle suggesting that one growth increment was laid down pertide. Band widths were unusually small compared with those ofbivalves or gastropods, probably because the shell is dividedinto eight growing plates. Overall rates of growth calculatedfrom band widths were 1–2 mm per month, comparable withfield estimates. (Received 13 February 1984;