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The dorsal eye of the dragonfly Sympetrum: specializations for prey detection against the blue sky (1995)

Labhart, T. ; Nilsson, D.-E.

Springer

Journal of comparative physiology 176 (1995), S. 437-453

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ISSN: 1432-1351

Keywords: Compound eye ; Dragonfly ; Electrophysiology ; Optics ; Photochemistry

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Abstract Dragonflies of the genus Sympetrum have compound eyes conspicuously divided into dorsal and ventral regions. Using anatomical, optical, electrophysiological, in-vivo photochemical and microspectrophotometrical methods, we have investigated the design and physiology of the dorsal part which is characterized by a pale yellow-orange screening pigment and extremely large facets. The upper part of the yellow dorsal region is a pronounced fovea with interommatidial angles approaching 0.3°, contrasting to the much larger values of 1.5°–2° in the rest of the eye. The dorsal eye part is exclusively sensitive to short wavelengths (below 520 nm). It contains predominantly blue-receptors with a sensitivity maximum at 420 nm, and a smaller amount of UV-receptors. The metarhodopsin of the blue-receptors absorbs maximally at 535 nm. The yellow screening pigment transmits longwavelength light (cut-on 580 nm), which increases the conversion rate from metarhodopsin to rhodopsin (see Fig. 11a). We demonstrate that because of the yellow pigment screen nearly all of the photopigment is in the rhodopsin state under natural conditions, thus maximizing sensitivity. Theoretical considerations show that the extremely long rhabdoms (1.1 mm) in the dorsal fovea are motivated for absorption reasons alone. A surprising consequence of the long rhabdoms is that the sensitivity gain, caused by pumping photopigment into the rhodopsin state, is small. To explain this puzzling fact we present arguments for a mechanism producing a gradient of rhodopsin concentration along the rhabdom, which would minimize saturation of transduction units, and hence improve the signal-to-noise ratio at high intensities. The latter is of special importance for the short integration time and high contrast sensitivity these animals need for spotting small prey at long distances.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00196410

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Effects of energy deprivation on the fly pupil mechanism: evidence for a rigor state (1994)

Jonson, A. -C. Järemo ; Nilsson, D. -E.

Springer

Journal of comparative physiology 174 (1994), S. 701-706

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ISSN: 1432-1351

Keywords: House fly ; Compound eye ; Pupil mechanism ; Pigment migration ; Anoxia

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Abstract The energy dependence of the pupil pigment-migrations in the fly Musca domestica was studied in live animals, using optical techniques and nitrogen-gas induced anoxia. The results obtained can be summarized in 3 points: 1. Energy deficiency can make the pupil mechanism stop in any state, extreme or intermediate. 2. Anoxia induced during intermittent stimulation makes the pupil stop in the closed state (aggregated pigment granules). 3. During long-term anoxia the pupil very slowly opens (dispersal of pigment granules), irrespective of ambient intensity. The slow anoxic opening (point 3) is more than 1000 times slower than that predicted for free diffusion of pigment granules in water. Assuming realistic values of cytoplasm viscosity, this implies that anoxia causes the pigment granules to attach to rigid structures in the cells, in analogy with the rigor state in anoxic muscles. The rigor phenomenon in the pupil mechanism prevents experimental discrimination between active and passive processes of pigment migration. Normal pupil opening has a time course which agrees reasonably with a passive diffusion process, but it is argued that an active transportation of granules away from the rhabdom is more likely in the dark adapted eye.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00192719

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Intensity and polarization of the eyeshine in butterflies (1989)

Nilsson, D. -E. ; Howard, J.

Springer

Journal of comparative physiology 166 (1989), S. 51-56

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ISSN: 1432-1351

Keywords: Compound eye ; Optics ; Insects

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary The compound eyes of most diurnal butterflies have a reflecting tapetum below the retina. Light that enters the eye is guided down the rhabdom, reflected by the tapetum, and then guided back up the rhabdom. The light that is not absorbed by the rhabdom is reemitted and gives rise to an eyeshine. We have measured the fraction of the incident light that is re-emitted, and also the degree to which this light retains its original polarization. The following conclusions are drawn: 1. Even at the wavelength where the eyeshine is most intense, only a few percent of the incident photons are re-emitted. 2. The tapetum acts as a plane mirror that preserves polarization. 3. The light that passes through the rhabdom in second-order waveguide modes is depolarized to a greater extent than the light contained in first-order modes. The depolarization is expected to decrease only slightly the polarization sensitivity of the retina. 4. Theoretical modelling of the waveguide properties of the rhabdom provided a way of using depolarization measurements for estimating the refractive index of the rhabdom. The measured amount of depolarization is consistent with the dispersion of phase velocities of different second-order modes propagating in a rhabdom of refractive index 1.363.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00190209

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Fine structure and optical properties of an ostracode (Crustacea) nauplius eye (1981)

Andersson, A. ; Nilsson, D. -E.

Springer

Protoplasma 107 (1981), S. 361-374

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ISSN: 1615-6102

Keywords: Nauplius eye ; Optics ; Ostracoda

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary InNotodromas monachus, the three cups of the nauplius eye are formed by four pigment cells. The insides of the cups are lined with tapetal cells, which produce several layers of reflecting crystals. The reflecting crystals form a concave mirror in each cup upon which the retinular cells rest. The two-celled rhabdoms are few and perpendicular to the tapetal layer. The axons from the tripartite eye leave the retinular cells distally in three separate groups. The eye is thus of the inverse type. Large lens cells, with a low refractive index, are present in the open part of each cup. Distal to the lens cells, highly refractive lenses are formed in the cuticle. These lenses serve to decrease the effective curvature of the mirrors, thus enabling the reflectors to produce a focused image on the retina. The ventral cup differs by the lack of a cuticular lens and has degenerated-appearing cellular elements. The investigated nauplius eye is the only one known with both a mirror and a highly refractive lens in the dioptric apparatus.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01276836

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