Spatial orientation of rainbow trout to plane-polarized light: The ontogeny of E-vector discrimination and spectral sensitivity characteristics

Summary The results of this study demonstrate that trout (Salmo gairdneri) are capable of orienting to polarized light fields. The spectral composition of the polarized light fields can significantly influence the orientation of trout. Rainbow trout exhibit ontogenetic losses in orientation to polarized light fields which appears coincident with the ontogenetic loss of the UV-sensitive cones. Trout were trained to swim to a refuge located at one end of the training tank under a polarized light field. The E-vector of the polarized light field was oriented parallel or perpendicular to the long axis of the training tank. Trained fish were released in a circular test tank and their angular response scored. Under a white plus ultraviolet polarized light field, trout oriented in the trained E-vector orientation. For instance, fish trained under a parallel E-vector orientation exhibited angular responses close to parallel in the test tank. However, when the spectral composition of the polarized light field was manipulated, the accuracy of spatial orientation of the trout varied. Trout weighing about 30 g exhibited accurate orientation to the white plus UV polarized light field. The trout were incapable of orientation at a body weight of 50 to 60 g.     

Structural specializations of the cornea and retina at the dorsal rim of the compound eye in hymenopteran insects

Summary Structurally specialized ommatidia at the dorsal rim of the compound eyes of honey bees have been shown to be indispensable for polarized skylight navigation. In this study numerous other hymenopteran genera belonging to various superfamilies are shown to exhibit similar specializations in this part of the eye: (1) The cornea is penetrated by pore canals, which affect the optics of the ommatidia by scattering the light falling into the eye. In Andrena and Ammophila the cornea contains extensive cavities. (2) Each retinula contains 9 long receptor cells as opposed to 8 long ones in the adjacent dorsal area, and the rhabdom area is increased by a factor of up to 2. In all ant species examined there are no corneal but only retinal specializations at the dorsal rim of the eye. They include a specially shaped rhabdom as in Cataglyphis, in which polarization vision has also been demonstrated.     

The effects of the general anaesthetic isoflurane on the honey bee (Apis mellifera) circadian clock

General anaesthesia administered during the day has previously been shown to phase shift the honey bee clock. We describe a phase response curve for honey bees (n=105) to six hour isoflurane anaesthesia. The honey bee isoflurane PRC is “weak” with a delay portion (maximum shift of –1.88 hours, circadian time 0 – 3) but no advance zone. The isoflurane-induced shifts observed here are in direct opposition to those of light. Furthermore, concurrent administration of light and isoflurane abolishes the shifts that occur with isoflurane alone. Light may thus provide a means of reducing isoflurane–induced phase shifts.     

The ultrastructural organization of the visual system of the wax moth,Galleria mellonella: The retina

Summary The ultrastructural organization of ommatidial components of the retina of the moth, Galleria mellonella are described from electron microscopic observations. Each ommatidium is composed of 12 common retinula cells and one basal eccentric cell. The retinula cells are connected together by a desmosomal strip along their length. The rhabdom occupies the basal thirty percent of the ommatidium and can be divided into nine segments of parallel microvilli. Several cells may contribute to an individual rhabdomere. The rhabdomeres are arranged in a cross with single cell rhabdomeres lying between the arms of the cross. Thin sections of ommatidium absorb polarized light differentially. The total amount of plane polarized light absorbed varies with angle of rotation for an entire ommatidium but there are also differences between the amount of absorption of adjacent rhabdomeric segments. Galleria appears to be the only lepidopteran in which the possibility of the polarized light reception has been reported.     

Phytochrome-mediated branch formation in protonemata of the mossCeratodon purpureus

We have analyzed light induction of side-branch formation and chloroplast re-arrangement in protonemata of the mossCeratodon purpureus. After 12 hr of dark adaptation, the rate of branch formation was as low as 5%. A red light treatment induced formation of side branches up to 75% of the dark-adapted protonema. The frequency of light induced branch formation differed between cells of different ages, the highest frequency being found in the 5th cell, the most distal cell studied from the apex. We examined the effect of polarized light given parallel to the direction of filament growth. The position of branching within the cell depended on the vibration plane of polarized red light. Branch formation was highest when the electric vector of polarized light vibrates parallel to the cell surface and is fluence rate dependent. The positional effect of polarized red light could be nullified to some extent by simultaneous irradiation with polarized far-red light. An aphototropic mutant,ptr116, shows characteristics of deficiency in biosynthesis of the phytochrome chromophore and exhibits no red-light induced branch formation. Biliverdin, a precursor of the phytochrome chromophore, rescued the red-light induced branching when added to the medium, supporting the conclusion that phytochrome acts as photoreceptor for red light induced branch formation. The light effect on chloroplast re-arrangement was also analyzed in this study. We found that polarized blue light induced chloroplast re-arrangement in wild-type cells, whereas polarized red light was inactive. This result suggests that chloroplast re-arrangement is only controlled by a blue light photoreceptor, not by phytochrome inCeratodon.     

Scanning eye movements of the stomatopod crustacean,Neogonodactylus oerstedii,in polarized light fields

ABSTRACT

Stomatopod crustaceans have highly mobile, independently moving compound eyes that are sensitive to both linearly and circularly polarized light. They rotate their eyes to predictable angles when viewing a linearly polarized target, and they scan their eyes frequently to sample the visual field. Angles of scans are roughly perpendicular to the plane of the midband (a set of specialized parallel rows of equatorial ommatidia). We investigated scanning eye movements in one Caribbean stomatopod species (Neogonodactylus oerstedii) in uniform visual fields that were vertically polarized, horizontally polarized, or depolarized. We found that mean eye rotation and scan angles differed significantly among these different treatments. Average scan angles differed by 12°, being more horizontal in a vertically polarized field than in a horizontally polarized one, and also more horizontal in a vertically polarized field than in a depolarized field. Thus, these stomatopods adjusted visual scanning to the polarization of the visual environment.     

Spatial orientation of trout to partially polarized light

Summary The results of this study reveal that rainbow trout (Oncorhyncus mykiss formerly Salmo gairdneri) are capable of orienting to polarized light fields, and that the degree of polarization of the polarized light field affects the accuracy of orientation behavior. As previously shown, rainbow trout can accurately orient to a plane polarized light field after several sessions of food-rewarded training. The present data demonstrate that the accuracy of such orientation decreases the degree of polarization of the plane-polarized light field is lowered. In testing sessions, different concentrations of latex beads were introduced into a cuvette positioned below the light source to degrade the degree of polarization. There was evidence that trout could still detect the evector and use it in making orienting responses when the light was only 65% polarized. However, most of the test trout did not demonstrate orienting ability at levels of polarization below the 75% level.     

Structural reactions to polarized light of microvilli in photoreceptor cells of the moth Spodoptera

Summary Intact armyworm moths (Spodoptera exempta, Farn. Noctuidae) were illuminated by polarized monochromatic light to induce structural changes in the rhabdomeres of the compound eyes. The degree of distortion of their microvilli depends on the light energy absorbed per time unit. Under polarized light, the number of quanta absorbed varies with the position of the plane of polarization relative to the axis of the microvilli (intrinsic dichroism). Therefore, in Spodoptera, different degrees of deformations could be demonstrated in differently oriented rhabdomeres of both types of ommatidia. Moreover, in rhabdoms of the lobed type with fan-like arranged microvilli, different reactions were regularly seen in differently oriented microvilli of one rhabdomere. This indicates that microvilli may react to light individually.Supported by Deutsche Forschungsgemeinschaft, Sonderforschungsbereich 114 (Bionach)     

Die Orientierung der Trichterspinne nach polarisiertem Licht

Summary The spider Agelena labyrinthica (Clerck) orients its movements by means of polarized light even if the reflection pattern of the web is not visible. If the spider is not permitted to see the overhead source of polarized light while the reflection pattern from the substratum is still visible, its orientation is not influenced by rotation of the polaroid. For this reason Agelena's orientation by means of polarized light must be based on a direct perception of the light's plane of vibration.     

Die Sehzellen der Insekten als Analysatoren für Polarisiertes Licht

Summary The response of single photoreceptor cells of the compound eye of Calliphora erythrocephala to the rotation of the plane of polarized light was measured with intracellular capillary electrods. Of 149 cells which were tested, 74 indicated no influence of the direction of polarization. For the remainder of the cells, with a constant position of the electrodes relative to the incidence of light, the plane of polarization to which the response was maximal, varied. This shows that the model suggested by Autrum and Stumpf (1950) for the analysis of polarized light is the correct one. The objections which have been raised against this model are criticized and refuted.

---

---

Mit Unterstützung der Deutschen Forschungsgemeinschaft.     

A Honey Bee (Apis mellifera) Light Phase Response Curve

The authors report a phase response curve (PRC) for individual honey bees (Apis mellifera) to single 1-h light pulses (1000 lux) using an Aschoff Type 1 protocol (n?=?134). The bee PRC is a weak (Type 1) PRC with a maximum advance of 1.5?h between circadian time (CT) 18 and 3 and a maximum delay of 1.5?h between CT 12 and 18. This is the first published honey bee light PRC and provides an important resource for chronobiologists and honey bee researchers. It may also have practical applications for what is an economically important species frequently transported across different time zones. (Author correspondence: G.warman@auckland.ac.nz)     

Simulation of phototaxis in the flagellateEuglena gracilis

A three-dimensional model of the flagellateEuglena gracilis was developed to simulate phototaxis and movement in space. The simulation of the phototactic behavior was compared with thein vivo behavior in order to determine the mechanism of orientation with respect to light. Phototactic behavior with respect to one light source, can be explained by the shading hypothesis as well as by a dichroic orientation of the absorbing vectors of the photoreceptor pigments. In contrast, the behavior of the cells when exposed to two perpendicular light beams is not compatible with the shading hypothesis. Likewise, the phototactic orientation of stigmaless cells cannot be accounted for on the basis of the shading hypothesis. In contrast, simulations andin vivo observations of the behavior under polarized light strongly indicate the validity of the dichroic orientation of the photoreceptor pigments.     

Tool for genomic selection and breeding to evolutionary adaptation: Development of a 100K single nucleotide polymorphism array for the honey bee

High‐throughput high‐density genotyping arrays continue to be a fast, accurate, and cost‐effective method for genotyping thousands of polymorphisms in high numbers of individuals. Here, we have developed a new high‐density SNP genotyping array (103,270 SNPs) for honey bees, one of the most ecologically and economically important pollinators worldwide. SNPs were detected by conducting whole‐genome resequencing of 61 honey bee drones (haploid males) from throughout Europe. Selection of SNPs for the chip was done in multiple steps using several criteria. The majority of SNPs were selected based on their location within known candidate regions or genes underlying a range of honey bee traits, including hygienic behavior against pathogens, foraging, and subspecies. Additionally, markers from a GWAS of hygienic behavior against the major honey bee parasite Varroa destructor were brought over. The chip also includes SNPs associated with each of three major breeding objectives—honey yield, gentleness, and Varroa resistance. We validated the chip and make recommendations for its use by determining error rates in repeat genotypings, examining the genotyping performance of different tissues, and by testing how well different sample types represent the queen's genotype. The latter is a key test because it is highly beneficial to be able to determine the queen's genotype by nonlethal means. The array is now publicly available and we suggest it will be a useful tool in genomic selection and honey bee breeding, as well as for GWAS of different traits, and for population genomic, adaptation, and conservation questions.     

Evidence for true polarization vision based on a two-channel analyzer system in the eye of the water bug,Notonecta glauca

Summary Water bugs (Notonecta glauca) were set into flight in a room with a homogeneously illuminated ceiling and a light-emitting platform on the floor. In these conditions polarized UV light from the platform was more effective in causing the animals to fly down to the surface of the platform than was unpolarized UV light several times as intense. Experiments with an array of baffles that restricted the directions from which the polarization film on the platform could be seen showed that the polarized UV light is effective in eliciting descent only when the e-vector is perpendicular to the median sagittal plane of the animal (horizontal). It can be concluded that polarized UV light with horizontal e-vector is distinguished, as a special sensory quality, from unpolarized UV light.Notonecta thus provides an example of true polarization vision.The special orthogonal arrangement of the microvilli in the rhabdomeres of the UV visual cells in the ventral part of the eye (cf. Schwind 1983 b and Schwind et al., in press) is suggestive with regard to polarization vision. The microvilli of the two UV visual cells in the ommatidia looking forward and down are horizontal and vertical, respectively, and hence could serve as a two-channel analyzer system capable of distinguishing the polarized UV light reflected by a water surface from unpolarized UV light.     

The dynamics of sleep-like behaviour in honey bees

At night, honey bees pass through a physiological state that is similar to mammalian sleep. Like sleep in mammals, sleep-like behaviour in honey bees is an active process. This is expressed most clearly in these insects by spontaneous antennal movements which appear at irregular intervals throughout the night and interrupt episodes of antennal immobility. Here we present a newly developed video technique for the continuous recording of the position and movements of the bee's antennae. The same technique was used to record head inclination and ventilatory movements. Despite the constancy of the ambient temperature, the magnitudes of antennae-related parameters, as well as head inclination and ventilatory cycle duration, displayed dynamic unimodal time-courses which exhibited a high degree of temporal covariance. The similarity between these time-courses and the nightly time-course of the reaction threshold for a sensory stimulus, investigated previously, indicates that, in honey bees, deepest "sleep" and least ventilatory activity occur at the same time (in the 7th hour of the rest phase).Abbreviations DD continuous darkness - EMG electromyogram - LD periodic alternation between light (L) and darkness (D) - MEST Middle European Summer Time (UTC+2 h); - UV ultraviolet This paper is dedicated to Professor Martin Lindauer, who—to our knowledge—was the first to meticulously record the nightly behaviour of honey bees (Lindauer 1952) and who also inspired one of us (W.K.) to investigate antennal motility during nightly rest in these animals.     

Population structure of honey bees in the Carpathian Basin (Hungary) confirms introgression from surrounding subspecies

Carniolan honey bees (Apis mellifera carnica) are considered as an indigenous subspecies in Hungary adapted to most of the ecological and climatic conditions in this area. However, during the last decades Hungarian beekeepers have recognized morphological signs of the Italian honey bee (Apis mellifera ligustica). As the natural distribution of the honey bee subspecies can be affected by the importation of honey bee queens or by natural gene flow, we aimed at determining the genetic structure and characteristics of the local honey bee population using molecular markers. All together, 48 Hungarian and 84 foreign (Italian, Polish, Spanish, Liberian) pupae and/or workers were used for mitochondrial DNA analysis. Additionally, 53 sequences corresponding to 10 subspecies and the Buckfast hybrid were downloaded from GenBank. For the nuclear analysis, 236 Hungarian and 106 foreign honey bees were genotyped using nine microsatellites. Heterozygosity values, population‐specific alleles, FST values, principal coordinate analysis, assignment tests, structure analysis, and dendrograms were calculated. Haplotype and nucleotide diversity values showed moderate values. We found that one haplotype (H9) was dominant in Hungary. The presence of the black honey bee (Apis mellifera mellifera) was negligible, but a few individuals resembling other subspecies were identified. We proved that the Hungarian honey bee population is nearly homogeneous but also demonstrated introgression from the foreign subspecies. Both mitochondrial DNA and microsatellite analyses corroborated the observations of the beekeepers. Molecular analyses suggested that Carniolan honey bee in Hungary is slightly affected by Italian and black honey bee introgression. Genetic differences were detected between Polish and Hungarian Carniolan honey bee populations, suggesting the existence of at least two different gene pools within A. m. carnica.     

Simulation and Analytical Study of Optical Complex Field in Nano-corral Slits Plasmonic Lens

Although spiral plasmonic lens has been proposed as circular polarization analyzer, there is no such plasmonic nanostructure available for linear polarization. In the current work, we have designed nano-corral slits (NCS) plasmonic lens, which focuses the x- and y-polarized light into spatially distinguished plasmonic fields. We have calculated analytically and numerically the electric field intensity and phase of the emission from nano-corral slits plasmonic lens with different pitch lengths under various polarizations of the illumination. It has been shown that one can control the wave front of the output beam of these plasmonic lenses by manipulating the illumination of both circular and linear polarization. Our theoretical study in correlation with FDTD simulation has shown that NCS plasmonic lens with pitch length equal to λ_spp produces scalar vortex beam having optical complex fields with helical wave front and optical singularity at the center under circular polarization of light. When NCS lens (pitch = λ_spp) is illuminated with linearly polarized light, it exhibits binary distribution of phase with same electric field intensity around the center. However, with pitch length of 0.5λ_spp, NCS shows linear dichroism under linearly polarized illumination unlike spiral plasmonic lens (SPL) eliminating the use of circularly polarized light. Optical complex fields produced by these NCS plasmonic lenses may find applications for faster quantum computing, data storage, and telecommunications.

     

Social pleiotropy and the molecular evolution of honey bee vitellogenin

In this issue of Molecular Ecology, Kent et al. (2011) describe the adaptive evolution of honey bee vitellogenin that belongs to a phylogenetically conserved group of egg yolk precursors. This glyco‐lipoprotein leads a double life: it is central to egg production in the reproductive queen caste, and a regulator of social behaviour in the sterile worker caste. Does such social pleiotropy constrain molecular evolution? To the contrary; Kent et al. show that the vitellogenin gene is under strong positive selection in honey bees. Rapid change has taken place in specific protein regions, shedding light on the evolution of novel vitellogenin functions.     

Alarm pheromone perception in honey bees is decreased by smoke (Hymenoptera: Apidae)

The application of smoke to honey bee(Apis mellifera) antennae reduced the subsequent electroantennograph response of the antennae to honey bee alarm pheromones, isopentyl acetate, and 2-heptanone. This effect was reversible, and the responsiveness of antennae gradually returned to that of controls within 10–20 min. A similar effect occurred with a floral odor, phenylacetaldehyde, suggesting that smoke interferes with olfaction generally, rather than specifically with honey bee alarm pheromones. A reduction in peripheral sensitivity appears to be one component of the mechanism by which smoke reduces nest defense behavior of honey bees.