Blue adaptation: An experimental tool for the study of visual receptor mechanisms and behaviour of Drosophila

Physiological and behavioural studies with Drosophila to elucidate visual mechanisms have exploited the bi-stability of the visual pigment in the peripheral retinula cells R1–6, and the off-on switch action of blue and orange light. Measurements of flicker fusion and response waveform from both receptor and lamina regions prior and subsequent to blue adaptation, which induces a prolonged depolarising afterpotential and loss of visual function in R1–6, show these retinula cells to have a high fusion frequency and R7/8, the central retinula cells, a lower fusion frequency. Such measurements also allow analysis of the extracellular response in terms of contributing cells, and its potential for studying the fly's ability to respond to various potential visual cues such as a rotating plane of polarised light. Blue adapted flies fail to fixate normally a black stripe, confirming a role for R1–6 in orientation behaviour requiring a competent degree of acuity.Based on material presented at the European Neurosciences Meeting, Florence, September 1978     

A comparative study of specific chromatic adaptation of the wildtype and trp mutant of Drosophila melanogaster

The trp mutant of Drosophila melanogaster was re-examined and compared with the wildtype using monochromatic blue and orange light to manipulate the bi-stable visual pigment states in the peripheral retinula cells R1-6 of white-eyed flies. Recovery of sensitivity by application of orange light either during or after blue-adaptation is different in w;trp flies from that in bw;cn flies and does not proceed as predicted from the trp genotype. Blue-adaptation by isolating the activity of the central retinula cells confirms that the trp lesion affects these receptors also.     

The organization of the lamina ganglionaris of the hemipteran insects,Notonecta glauca,Corixa punctata and Gerris lacustris

Summary Neuronal elements, i.e. first and second order neurons, of the first optic ganglion of three waterbugs, N. glauca, C. punctata and G. lacustris, are analyzed on the basis of light and electron microscopy.Eight retinula cell axons, leaving each ommatidium, disperse to different cartridges as they enter the laminar outer plexiform layer. Such a pattern of divergence is one of the conditions for neuronal superposition; it is observed for all three species of waterbugs. The manner in which the receptors of a single bundle of ommatidia split of within the lamina, whereby information from receptors up to three or five horizontal rows away can converge upon the same cartridge, differs among the species. Six of the eight axons of retinula cells R1-6, the short visual fibers end at different levels within the bilayered lamina, whereas the central pair of retinula cells R7/8, the long visual fibers, run directly through the lamina to a corresponding unit of the medulla. Four types of monopolar cells L1–L4 are classified; their branching patterns seem to be correlated to the splitting and termination of retinula cell axons. The topographical relationship and synaptic organization between retinula cell terminals and monopolar cells in the two laminar layers are identified by examination of serial ultrathin sections of single Golgi-stained neurons.An attempt is made to correlate some anatomical findings, especially the neuronal superposition, to results from physiological investigations on the hemipteran retina.     

The effect of short wavelength light on retinula cell structure in white-eye Drosophila.

Recent electron microscopic examination of the retinula cells of white-eyed fruitflies has shown gross disruption of the ordered membrane system of the rhabdomeres, and extensive vesiculation of retinula cells 1 to 6 within each ommatidium following blue irradiation. Central retinula cells 7 and 8 are unaffected. The selective disruption is not observed in white-eyed fruitflies similarly irradiated with equal-energy yellow light.     

Photoreceptor projection and termination pattern in the lamina of gonodactyloid stomatopods (mantis shrimp)

The apposition compound eyes of gonodactyloid stomatopods are divided into a ventral and a dorsal hemisphere by six equatorial rows of enlarged ommatidia, the mid-band (MB). Whereas the hemispheres are specialized for spatial vision, the MB consists of four dorsal rows of ommatidia specialized for colour vision and two ventral rows specialized for polarization vision. The eight retinula cell axons (RCAs) from each ommatidium project retinotopically onto one corresponding lamina cartridge, so that the three retinal data streams (spatial, colour and polarization) remain anatomically separated. This study investigates whether the retinal specializations are reflected in differences in the RCA arrangement within the corresponding lamina cartridges. We have found that, in all three eye regions, the seven short visual fibres (svfs) formed by retinula cells 1–7 (R1–R7) terminate at two distinct lamina levels, geometrically separating the terminals of photoreceptors sensitive to either orthogonal e-vector directions or different wavelengths of light. This arrangement is required for the establishment of spectral and polarization opponency mechanisms. The long visual fibres (lvfs) of the eighth retinula cells (R8) pass through the lamina and project retinotopically to the distal medulla externa. Differences between the three eye regions exist in the packing of svf terminals and in the branching patterns of the lvfs within the lamina. We hypothesize that the R8 cells of MB rows 1–4 are incorporated into the colour vision system formed by R1–R7, whereas the R8 cells of MB rows 5 and 6 form a separate neural channel from R1 to R7 for polarization processing.This research was supported by the Swiss National Science Foundation (PBSKB-104268/1), the Australian Research Council (LP0214956) and the American Air Force (AOARD/AFOSR) (F62562-03-P-0227).     

Frequency dependent flicker response enhancement in the lamina ganglionaris ofDrosophila

Summary At low light intensity and within the narrow frequency range of 55 to 66 s^–1, the eye ofDrosophila will follow a flashing light source by enhancing it's flicker response to every other flash. By contrast, at lower and higher frequencies the eye will follow every cycle of a respective flash frequency upto a fusion point around 200 s^–1.While the receptor cells involved are retinula cells R1–6, the flicker response enhancement is established to originate postsynaptically in the Large Monopolar Cells of the lamina with which the peripheral retinula cells synapse, and which respond with the cornealpositive on-transient component of the ERG. Not only is a prescribed frequency required for the enhancement, but also continuity of cue — since brief periods of light flashes within the required frequency range are resolved at every cycle.The flicker response behaviour provides further credence to the existence of fine tuning mechanisms together with amplification within the lamina neuropile.We are grateful to the late Dr. Richard Wright for his comments, and to Professor Aubrey Manning for the hospitality his Department gave to N.L.     

Visual signals in the courtship of Drosophila melanogaster

Drosophila melanogaster carrying either of the mutations sev or dipp⁶ show defective phototactic behaviour owing to deficiencies in the processing of visual information perceived by the central retinula cells (R7, R8). Mutant females show increased time to mating because the deficient visual input via this subsystem has an inhibitory effect on female receptivity. Similarly, deficient input through the peripheral retinula cells (R1–R6) also makes females sexually unreceptive. Thus females require appropriate visual stimulation through both subsystems to become maximally sexually receptive. One major source of this stimulation is the red eye of the male.     

The first optic ganglion of the bee

Each visual unit (ommatidium) of the compound eye of the honey bee contains nine retinula cells, six of which end as axons in the first synaptic ganglion, the lamina, and three in the second optic ganglion, the medulla. A technique allowing light- and electron microscopy to be performed on the same silver-impregnated sections has made it possible to follow all types of retinula axons of one ommatidium to their terminals in order to study the shape of the terminal branches with their position in the cartridge. 1. The axons of retinula cells 1-6 (numbered according to Menzel and Snyder, 1974) end as three different types of short visual fibres (svf) in the lamina; the axons of retinula cells 7-9 run through the lamina to terminate in the medulla and are known as long visual fibres (lvf). Retinula cells of each type are identified by the location of their cell bodies and by the direction of their microvilli. The retinula cells 1 and 4 (group I according to Gribakin, 1967) end as svf type 1 with three tassel-like branches in stratum B of the first synaptic region. The pair of cells 3, 6 and the pair 2, 5 (group II) end in the first synaptic region in stratum A. Cells 3 and 6 have forked endings, svf type 2, whereas cells 2 and 5 have tapered endings, svf type 3. The remaining retinula cells 7, 8 and 9 have long fibres. Nos. 7 and 8 (group III) have tapered endings and are termed lvf types 1 and 2, respectively. The 9th cell is the lvf type 3 with a highly branched ending. 2. The nine axons in the bundle from one ommatidium have relative positions which do not change from the proximal retina to the monopolar cell body layer. 3. By following silver-stained retinula cells and their corresponding axons, it is possible to describe mirror-image arrangements of fibres in the axon bundles in different parts of the eye. This correlation of numbered retinula cells with specific axon types, together with the highly organized pattern in an axon bundle, allows the correlation between histological and physiological findings on polarization and colour perception.     

The retina-lamina projection in the visual system of the bee,Apis mellifera

Single Golgi impregnated visual cells and their axons were treated from the retina to the first synaptic layer (lamina) in serial electron microscopic sections. This analysis of the retina-lamina projection was undertaken in the upper dorso-median eye region which is known to be involved in the perception of polarized light. For identification of individual visual cells and their fibres a numbering system was used which relates the number of each of the nine visual cells within one retinula to the transverse axis of the rhabdom (TRA) (Fig. 1). Because of the twist of the retinula along its course to the basement membrane (Fig. 6), individual visual cells change their position relative to any eye-constant co-ordinate system. Each axon bundle originating from one 9-celled retinula performs a 180 degrees-rotation before entering the lamina (Fig. 2). The direction of rotation (clockwise or counter-clockwise), which may differ even between adjacent bundles, is related to the two mirror-image types of rhabdoms in the corresponding retinulae and is opposite to the direction of rhabdom twist. Thus, even in small groups of the in total 5500 ommatidia in the eye of the bee, two types of retinulae exist which can be characterized by the geometry of the rhabdoms as well as by the direction of rotation of the retinulae and the axon bundles (Fig. 1). Visual cell numbers 1, 2, and 9, the microvilli of which are oriented in the direction of TRA, form three long visual fibres terminating in the second synaptic layer (medulla). In cross sections of laminar pseudocartridges they appear as the smallest fibre profiles arranged in a symmetrical line of the pseudocartridge bundle (=the transverse axis of the pseudocartridge; TPA) (Fig. 4). The remaining six fibres (cell numbers 3-8) only project to the lamina (short visual fibres; svf's). Two of them (cell numbers 5 and 6), which are the largest cells in the proximal retinula and have their microvilli perpendicularly arranged to TRA (Fig. 1), give rise to the two thickest axons of the underlaying pseudocartridge. In cross sections, t he connecting line of these two axons is orthogonally oriented to TPA (Fig. 5). A model was developed, in which all long visual fibres originate from ultraviolet receptors and in which the polarization sensitivity of the basal ninth cell is enhanced by the twist of the rhabdom. Finally, this model is discussed in light of behavioral experiments revealing the ultraviolet receptors as the only cells involved in the detection of polarized light.     

The role of retinula cell types in fixation behaviour of walkingDrosophila melanogaster

Summary Fixation behaviour of free walking wild typeDrosophila and various retinal mutants was tested in a circular arena. Optomotor response was also measured as a test of the function of R1-6.ora andsev,ora do not fixate a narrow stripe (10° or 20°, Fig. 1) but are able to orient towards broad stripes (110° or 180°, Fig. 1). The behaviour ofsev is not different from wild type. Fixation behaviour ofw rdgB is similar toora (Figs. 5, 6). The mutantora has a maximum optomotor response at low contrast frequencies (Fig. 2), but the threshold for this response is at least one log unit higher than in wild type orsev (Fig. 8). The light intensity threshold at 550 nm of fixation to a broad stripe (110°) is 1–2 log units higher inora than in wildtype, and 4 log units higher insev,ora and the structural brain mutantVam (Fig. 7).The conclusions are that retinula cells R1-6 mediate fixation to a narrow stripe at high and low ambient light intensities, and to a broad stripe at low ambient light levels. R8, possibly in conjunction with R1-6, contributes to orientation towards broad stripes at high light intensities. This hypothesis is supported by evidence that blue-adapted white-eyed flies are able to orient towards a broad stripe at high blue light intensities (Figs. 9 and 12). Blue adaptation totally eliminates the optomotor response (Figs. 10, 11) and so the optomotor response observed inora at low contrast frequencies (Figs. 2 and 8) is most likely due to the small remnants of the rhabdomeres of R1-6 that remain.Abbreviations PDA prolonged depolarising afterpotential - ERG electroretinogram     

Identificaton of UV,green and red receptors,and their projection to lamina in the cabbage butterfly,Pieris rapae

Summary The photoreceptors in the compound eye of a cabbage butterfly, Pieris rapae, were examined by conventional and intracellular-labeling electron microscopy by the use of the cobalt(III)-lysine complex as an ionized marker. Five types of spectral sensitivity were recorded intracellularly in electrophysiological experiments. They peaked at about 340, 380, 480, 560 and 620 nm, respectively. One of the distal retinula cells (R2) was a UV receptor, whereas the R4 distal retinula cell was a green receptor. The basal retinula cell, R9, was found to be a red receptor; it was localized near the basement membrane, having a bilobed cell body with an individual nucleus in each lobe. A small number of rhabdomere microvilli were present in a narrow cytoplasmic bridge connecting the two lobes. The axons of six retinula cells (R3–R8) in each ommatidium terminated at the cartridge in the lamina (short visual fiber), whereas those of the other three retinula cells, R1, R2 and R9, extended to the medulla (long visual fiber). The information from the UV and red receptors is therefore probably delivered directly to the medulla neurons, independent of that from the other spectral receptor types.     

Graded illumination potentials from retinula cell axons in the bug Lethocerus

Summary Intracellular responses to illumination have been recorded separately from the retinula cells and from their axons in the compound eyes of the giant water bug Lethocerus. The basic response in both places consists of an initial transient depolarisation followed by a plateau (Fig. 2). No action potentials were seen in either axons or retinula cells.The responses are graded according to the intensity of the stimulus, to its position within the visual field of the cells and to the plane of polarization of the light (Figs. 3, 4). The angle of acceptance (dark-adapted eyes) measured in either retinula cells or axons is 9°. Similarly, the average value of the sensitivity ratio to light polarised at orthogonal planes is 31 in both places.Experiments designed to reveal a presumed spike initiation region of the cells by reducing damage to the eye failed to reveal impulses. It is concluded that the receptor potential spreads electrotonically in the axon to the first synaptic region which lies up to 2 mm away. The values of membrane constants which would be required for conduction without severe decrement over such a distance are within the range measured in other systems.     

Ultrastructure of the single-chamber stemmata of Arge pagana (Panzer, 1798) (Hymenoptera: Argidae)

Stemmata are peculiar visual organs of most larvae in holometabolous insects. In Hymenoptera, Symphyta larvae exclusively possess a pair of stemmata, whose cellular organizations have not been thoroughly elucidated to date. In this paper, the morphology and fine structure of stemmata were investigated in the large rose sawfly Arge pagana (Panzer, 1798) using light and electron microscopy. The larvae possess a pair of stemmata, which belong to the “unicorneal composite eye” or single-chamber stemmata. Each stemma is composed of a biconvex cornea lens, a layer of corneagenous cells, numerous pigment cells, and hundreds of retinula cells. According to the number of retinula cells forming a rhabdom, the stemma can be divided into two regions, the larger Region I and the smaller Region II. The former occupies the largest area of the stemma and contains the majority of rhabdoms, each of which is formed by the rhabdomeres of eight retinula cells. The latter occupies a narrow posterior margin, where each rhabdom consists of nine retinula cells. Based on the different cellular organizations of rhabdoms, the stemma of Argidae is likely developed by the fusion of two types of ommatidial units.     

Wavelength-dependent polarization orientation in Daphnia

The ability to detect and use the polarization of light for orientation is widespread among invertebrates. Among terrestrial insects, the retinula cells that are responsible for polarization detection contain a single visual pigment, either ultraviolet or short (blue) wavelength sensitive. With the exception of a few aquatic insects, the visual pigments underlying polarization sensitivity in aquatic invertebrates have yet to be determined. Here we report that polarotaxis in Daphnia pulex, a freshwater crustacean, is wavelength dependent and most likely mediated by two visual pigments with absorbance maxima in the middle (green) and long wavelength (red) parts of the spectrum. This contrasts with the response of a closely related species, D. magna, in which polarotaxis is wavelength independent and based on a single middle wavelength visual pigment. The visual systems in Daphnia are the first among crustaceans shown to utilize a middle wavelength pigment for polarization detection and, in the case of D. pulex, the first shown to use more than one visual pigment for such a purpose.     

Retinal ultrastructure of the dorsal eye region of Pararge aegeria (Linné) (Lepidoptera: Satyridae)

We examined the fine structure of dorsal rim ommatidia of the compound eye of Pararge aegeria (Lepidoptera: Satyridae) and compared them with ommatidia of the large dorsal region described by Riesenberg (1983 Diploma, University of Munich). 1. The ommatidia of the dorsal rim show morphological specializations known to be typical of the perception of polarized light: (a) the dumb-bell-shaped rhabdoms contain linearly aligned rhabdomeres with only 2 orthogonally arranged microvilli orientations. The rhabdoms are composed of the rhabdomeres of 9 receptor cells, 8 of which are radially arranged. The rhabdomeres of receptor cells VI and V5, as well as D2, D4, D6 and D8 are dorsoventrally aligned, whereas the rhabdomeres of the cells H3 and H7 are perpendicular to them. The rhabdomere of the bilobed 9th retinula cell lies basally and is dorsoventrally aligned, where retinula cell VI and V5 are already axonal. (b) There is no rhabdomeric twist, and (c) the rhabdoms are rather short. 2. However, in the ommatidia of the large dorsal region, only 2 retinula cells (H3 and H7) are suitable for perception of polarized light. 3. Lucifer yellow and horse radish peroxidase were used as tracers to visualize the projections of retinula cell axons of the dorsal rim area and the large dorsal region into the optic neuropils (lamina and medulla). Two receptors (VI and V5) from both the dorsal rim area and the large dorsal region, have long visual fibres projecting into the medulla. The 7 remaining retinula cells of both eye regions, including those that meet the structural requirements for detection of polarized light in the large dorsal region, terminate in the lamina (short visual fibres). These results provide a starting point for further studies to reveal the possible neuronal pathways by which polarized light may be processed.     

The relative importance of ultraviolet and longer wavelengths in the response properties of fly visual systems

A generalized analysis of the generator potential responses of R1-6 cells of Calliphora provides remarkable information on the visual properties for the Diptera. This shows that, although these cells have two peak response sensivities for monochromatic stimuli at 350 and 480 nm under single color stimulus conditions, and when the background illumination is either zero or in the region of 450–560 nm, the sensitivity to ultraviolet light is practically eliminated for background illumination in either the ultraviolet or the region around 600 nm or when any simultaneous dynamic stimulus in the region of 480–550 nm is also applied. These results seem somewhat perplexing to an understanding of the behavioral vision properties. It also is not consistant with the concept that the ultraviolet response is initiated by a sensitizing pigment within these cells that transfers energy to the rhodopsin-metarhodopsin process. However, it strengthens other evidence that the limited condition of ultraviolet responses comes from interaction from R7,8 cells but does not play an important behavioral role in the visual system fed from cells R1-6. As discussed in this paper, any high level pattern recognition controlling behavioral response to ultraviolet stimuli comes from the R7,8 cell system.     

Vision in Drosophila: evidence for the involvement of retinula cells 1–6 in the orientation behaviour of Drosophila melanogaster

ABSTRACT. Orientation responses of wildtype red-eye, and mutant brown- and white-eye Drosophila melanogaster were studied in a circular arena. Freely walking flies ('closed-loop') were introduced into the arena and their orientations to a vertical black stripe of angular width 10> were recorded under different chromatic regimes. As has been reported previously, the accuracy of orientation and tropotactic responses were directly related to the extent of eye pigmentation. Orange-adaptation was found to have little effect on the accuracy of orientation, but blue-adaptation affected this orientation in all three phenotypes, with statistically significant diminutions in their responses. An electro-physiological study confirmed the inferred effect of blue-adaptation, namely that it causes a decreased sensitivity in retinula cells 1–6 by converting the visual pigment R480 to a stable metarhodopsin M580. It is concluded that these retinula cells are involved in orientation behaviour requiring a high degree of visual acuity in Drosophila.     

Experimental confinement of the transient receptor potential to the peripheral retinula cells in the trp mutant Drosophila: What it tells us about the mutation and visual function

By the use of appropriate light intensities the expression of the transient nature of the receptor potential observed in the trp mutant of Drosophila melanogaster can be confined to the peripheral retinula cells in which the visual pigment can also be manipulated predictably, affording an experimental means to probe in these receptors the relationship of the visual pigment to the “electrogenic membrane”. Repeated blue light exposures cause w;trp flies to respond in a manner like cn;bw flies in which the dark-adapted rhodopsin fraction is reduced to 0.5% of the normal level by vitamin A deprivation: this comparable response behaviour, since the amount of visual pigment in w;trp flies is normal, implies that only some subfraction of the photoequilibrium value of rhodopsin may be available. Recovery of the peripheral receptors' sensitivity in ambient light conditions which would render them insensitive by expression of the phenotype is paradoxical and allows a “wavelength effectivity” curve to be constructed which identifies the involvement of the rhodopsin. Resolution of the paradox is discussed.     

Expression of acetylcholinesterase during visual system development in Drosophila

As in other insects acetylcholine (ACh) and acetylcholinesterase (AChE) function in synaptic transmission in the central nervous system of Drosophila. Studies on flies mutant for AChE indicate that in addition to its synaptic function of inactivating acetylcholine, this neural enzyme is required for normal development of the nervous system (J.C. Hall, S.N. Alahiotis, D.A. Strumpf, and K. White, 1980, Genetics 96, 939-965; R.J. Greenspan, J.A. Finn, and J.C. Hall, 1980, J. Comp. Neurol. 189, 741-774). In order to understand what role AChE may play in neural development, it is necessary to know, in detail, where and when the enzyme appears. The use of monoclonal antibodies to localize AChE in the developing visual system of wild type Drosophila has yielded the novel observation that AChE appears in photoreceptor (retinula) cells 4-6 hr after they differentiate and 3 to 4 days before they are functional. Three days later the staining in the cell body of these cells is reduced. Because retinula cells have no functional connections at the time when AChE is first detected, AChE can not be performing its standard synaptic function. Subsequent to the reduction of AChE in the retinula cells, midway through the pupal stage, the enzyme accumulates rapidly in the neuropils of the optic lobes of the brain. Thus, there is a biphasic accumulation of AChE in the developing visual system with the enzyme initially being expressed in the retinula cells and accumulating later in the optic lobes.     

Regional differences in a nematoceran retina (Insecta,Diptera)

Summary The compound eye of Psychoda cinerea comprises two types of ommatidia, arranged so as to divide the retina into distinct dorsal and ventral regions. The P-type ommatidium, in the ventral part of the eye, differs fundamentally from the other dipteran ommatidia so far described, and is regarded as a primitive ommatidium. The acone dioptric apparatus is the same in both types, with a spherical lens and four Semper cells, the processes of which expand below the rhabdom to form a ring of pigment sacs. Only the distal region of the rhabdom is surrounded by a continuous ring of screening pigment, formed by 2 primary and 12–16 secondary pigment cells. The highly pigmented retinula cells penetrate the basement membrane proximally at about the level of their nuclei; in this region they are separated from the hemolymph by glial elements. The rhabdomeres R1–6 are fused to form a tube. The two types of ommatidia are defined by the arrangement of the retinula cells R7/8: in the T type the central rhabdomeres are one below the other, in the usual tandem position, whereas in the P type only R8 is central, with R7 in the peripheral ring. In the proximal region of the retina, retinula cells with parallel microvilli in neighboring ommatidia are joined in rows by lateral processes from the R8 cells. All the rhabdomeres are short and not twisted, which suggests that the retinula cells are highly sensitive to direction of polarization. The eye can adapt by a number of retinomotor processes. These findings, together with observations of behavior, imply that the psychodids have well-developed visual abilities.