Kinetics of oxygen consumption after a single flash of light in photoreceptors of the drone (Apis mellifera)

The time course of the rate of oxygen consumption (QO2) after a single flash of light has been measured in 300-micrometers slices of drone retina at 22 degrees C. To measure delta QO2(t), the change in QO2 from its level in darkness, the transients of the partial pressure of O2 (PO2) were recorded with O2 microelectrodes simultaneously in two sites in the slice and delta QO2 was calculated by a computer using Fourier transforms. After a 40-ms flash of intense light, delta QO2, reached a peak of 40 microliters O2/g.min and then declined exponentially to the baseline with a time constant tau 1 = 4.96 +/- 0.49 s (SD, n = 10). The rising phase was characterized by a time constant tau 2 = 1.90 +/- 0.35 s (SD, n = 10). The peak amplitude of delta QO2 increased linearly with the log of the light intensity. Replacement of Na+ by choline, known to decrease greatly the light-induced transmembrane current, caused a 63% decrease of delta QO2. With these changes, however, the kinetics of delta QO2 (t) were unchanged. This suggest that the recovery phase is rate-limited by a single reaction with apparent first-order kinetics. Evidence is provided that suggests that this reaction may be the working of the sodium pump. Exposure of the retina to high concentrations of ouabain or strophanthidin (inhibitors of the sodium pump) reduced the peak amplitude of delta QO2 by approximately 80% and increased tau 1. The increase of tau 1 was an exponential function of the time of exposure to the cardioactive steroids. Hence, it seems likely that the greatest part of delta QO2 is used for the working of the pump, whose activity is the mechanism underlying the rate constant of the descending limb of delta QO2 (t).     

The supply of metabolic substrate from glia to photoreceptors in the retina of the honeybee drone

1. The drone retina is composed essentially of only two types of cells: a population of identical photoreceptor cells occupying 38% of the volume is embedded in a syncytium of glia (called outer pigment cells). Nearly all the mitochondria are in the photoreceptors. 2. A retinal slice consumes 18 microliter O2 (ml tissue)-1 min-1 in the dark for up to 6 h, even without exogenous substrate; in 6 h this would require the equivalent of 127 mM glucose in the photoreceptors or 8.7 mg glycogen (ml tissue)-1. 3. Freshly dissected retinas contain about 45 mg glycogen (ml tissue)-1, but this appears, from electron micrographs and from the PAS reaction, to be exclusively in the glia. After superfusion with substrate-free Ringer solution for 30 min, slices of retina contained less than 20 microM glucose. It therefore appears that to sustain respiration, carbohydrate substrate must be transferred from the glia to the photoreceptors. 4. Even after 6 h superfusion with substrate-free Ringer solution O2 consumption (QO2) was not increased by exogenous glucose, pyruvate, trehalose or lactate, nor decreased by 2-deoxy-D-glucose. QO2 was increased 2-3 fold by either light stimulation or (for at least 20 min) by 50 microM dinitrophenol. 5. QO2 was only slightly reduced when Na-dependent glucose transport was inhibited either by reduction of extracellular [Na+], or the presence of phlorizin. 6. It is suggested that drone retinal function does not require the uptake of glucose by the photoreceptors, but that the glia do take up glucose.     

An electron microprobe analysis of photoreceptors and outer pigment cells in the retina of the honeybee drone

Summary Intracellular concentrations of elements were measured in the retina of the honeybee drone,Apis mellifera by electron microprobe X-ray analysis of frozen dried sections (Table 2). Before shock-freezing, slices of retina were superfused with Ringer solution, as in other work in which intracellular activities of Na⁺, K⁺ and Cl^– were measured with ion-selective microelectrodes. The results give no evidence for any binding or sequestering of these elements in the cells, with the possible exception of K in photoreceptors (Table 3). In the special case of Na in outer pigment cells,a _Na and [Na] were measured in the same piece of tissue: Na was present at a high concentration (55 mmol/l) but, again, we calculate that it was all freely dissolved in the cell water.It was estimated that the subrhabdomeric cisternae of the photoreceptors contained 2–3 mmol/l Ca; otherwise, their electrolyte composition was similar to that of the cytoplasm. [Na], [K] and [Cl] in the rhabdom were what would be expected if the spaces between the microvilli were filled with Ringer solution     

The perception of small objects by the drone honeybee

Drones (Apis mellifera ) were attracted to a lure scented with queen pheromone suspended at a height of 11–18m. An unscented test object, usually a black sphere, was lowered on a vertical string at a horizontal distance of 50 cm or 103 cm from the scented lure. Drones often made a rapid, direct, displacement from the scented lure to the test object. Drones responded to objects that subtended an angle as small as 0.41° which is less than the acceptance angle of a single ommatidium. We calculate that a drone can respond to a stimulus corresponding to a reduction in the light incident on one ommatidium at a time of 8%; the brevity of the stimulus on each ommatidium would seem to be a factor in the design of the eye.     

Light-dependent repetitive Ca2+ spikes induced by extracellular application of neomycin in honeybee drone photoreceptors

Photoreceptor cells of the honeybee drone fire, in the presence of the polycationic aminoglycoside neomycin, repetitive slow spike-like potentials superimposed on the receptor potential plateau phase. We have used conventional intracellular recordings and microfluorometric intracellular Ca²⁺ measurements to characterize these spike potentials. We have shown that the spike frequency increases in a light-intensity-dependent manner. The spikes are fired only when light stimuli depolarize the cell from a resting potential of −50 to −60 mV to at least −40 to −45 mV; they are tetrodotoxin insensitive and blocked by the Ca²⁺ channel blockers Ni²⁺, Cd²⁺, ω-agatoxin TK, verapamil and methoxyverapamil. Depolarization of the photoreceptors with high extracellular K⁺ in the presence of neomycin in darkness does not generate spikes. Small intracellular Ca²⁺ oscillations superimposed on the plateau phase of the light-induced increase in intracellular free Ca²⁺ concentration have a similar temporal pattern as the spike-like potentials. We conclude that the spike-like potentials require stimulation by light and are generated by voltage-dependent Ca²⁺ channels localized on the soma of the photoreceptors, distal to the basal lamina. Accepted: 16 March 2000     

The honeybee queen influences the regulation of colony drone production

Social insect colonies invest in reproduction and growth, buthow colonies achieve an adaptive allocation to these life-historycharacters remains an open question in social insect biology.Attempts to understand how a colony's investment in reproductionis shaped by the queen and the workers have proved complicatedbecause of the potential for queen–worker conflict overthe colony's investment in males versus females. Honeybees,in which this conflict is expected to be minimal or absent,provide an opportunity to more clearly study how the actionsand interactions of individuals influence the colony's productionand regulation of males (drones). We examined whether honeybeequeens can influence drone regulation by either allowing orpreventing them from laying drone eggs for a period of timeand then examining their subsequent tendency to lay drone andworker eggs. Queens who initially laid drone eggs subsequentlylaid fewer drone eggs than the queens who were initially preventedfrom producing drone eggs. This indicates that a colony's regulationof drones may be achieved not only by the workers, who buildwax cells for drones and feed the larvae, but also by the queen,who can modify her production of drone eggs. In order to betterunderstand how the queen and workers contribute to social insectcolony decisions, future work should attempt to distinguishbetween actions that reflect conflict over sex allocation andthose that reflect cooperation and shared control over the colony'sinvestment in reproduction.     

Is the membrane voltage amplifier of drone photoreceptors useful at physiological light intensities?

Free-flying drones (Apis mellifera) were attracted by pheromone to an elevated observation site where they looked for small distant objects, a visual task similar to nuptial pursuit. The brightness of the sky against which drones performed this task was measured as the radiance over a range of wavelengths covering the absorbance spectra of the principal drone rhodopsin and its metarhodopsin. This brightness varied relatively little, by just over one log unit. In laboratory experiments on the intact drone, the amplitude of photoreceptor responses to small decrements in intensity showed a marked maximum when the background intensity depolarized the cells to about –35mV. The radiance of this optimal background was only 0.2 log units greater than the sky radiance at which most drones were seen. It is argued that because of probable systematic errors the true difference may be less. It is known that in superfused retinal slices voltage-dependent sodium channels amplify small signals under these stimulus conditions. We therefore conclude that this amplification is useful for the major visual activity of the drone.     

Actions of neomycin on electrical light responses, Ca2+ release, and intracellular Ca2+ changes in photoreceptors of the honeybee drone

Neomycin, known to inhibit phospholipase C-mediated IP3 formation, was applied in the bath or injected into cells and its effects on electrical light responses were analyzed. Neomycin effects on inositol 1,4,5-trisphosphate- and Ca2+-induced Ca2+ release from the endoplasmic reticulum and/or the light-induced Ca2+ elevation were also studied. Neomycin (0.5 mmol x l(-1)) blocked inositol 1,4,5-trisphosphate-, caffeine-, and Ca2+-induced Ca2+ release. Bath application of neomycin decreased the sensitivity to 20-ms light flashes by a factor of up to 100 and slowed the kinetics of dim flash responses. Intracellularly injected neomycin desensitized the photoreceptors more than 1 log unit, increased the latency, and slowed the rate of rise of the light response. Neomycin (0.5 mmol x l(-1)) in the bath delayed and reduced the transient component of responses to 1-s steps of light at intermediate intensities. It also decreased and slowed the light-induced, and it blocked the caffeine-induced intracellular Ca2+ elevation. The combined pharmacological effects of neomycin are suggested to decrease the Ca2+-mediated amplification of the phototransduction cascade and the Ca2+-mediated acceleration of processes determining the kinetics of light responses.     

The initial response of Limulus ventral photoreceptors to bright flashes. Released calcium as a synergist to excitation

The leading edge of the response of Limulus ventral photoreceptors to brief flashes was investigated using a voltage clamp. The leading edge of responses increases linearly with flash intensity when dim flashes produce less than one photoisomerization per square micron of cell surface. Brighter flashes accelerate the initial portion of the response, resulting in a fourth-power relationship between the magnitude of the response at brief times after the flash and the flash intensity. The onset of this nonlinearity with increasing flash intensity is determined by the local density of photoisomerizations within the receptor. Responses to bright 10-15-mum-diam spots therefore rise faster than responses to diffuse flashes producing the same number of photoisomerizations within the receptor. Background illumination shortens the response latency and suppresses the initial nonlinearity. These phenomena can be explained by a model of transduction in which light activates two parallel cascades of reactions. Particles released by the first of these cascades open ionic channels, while the second produces an agent that accelerates the rate of production of particles by the first. Injection of the calcium buffer EGTA slows the initial portion of the response to bright flashes and suppresses its nonlinearity, which suggests that the accelerating agent released by the second cascade is calcium.     

Intracellular Ca2+ concentration and latency of light-induced Ca2+ changes in photoreceptors of the honeybee drone

We have measured Ca_i at rest and upon light stimulation in the photoreceptors of the honeybee drone microfluorometrically with the fluorescent Ca²⁺ indicator dyes fura-2, fluo-3 and Ca-green 5N.In darkness, Ca_i was 90 nM after 5 min of dark adaptation. A saturating light step caused Ca_i to rise in the bulk cytoplasm to 750 nM within 1 s. Our measurements with the low affinity dye Ca-green 5N showed that bright 1-s light flashes cause a rapid increase in Ca_i which was graded with stimulus intensity. Ca-green 5N fluorescence reached a peak in about 200 ms, and then decayed to a slightly lower sustained plateau. The fluorescence signal peaked, when the receptor potential was repolarizing from its peak to the plateau. This observation is in agreement with the proposal that the peak-to-plateau transition of the receptor potential is caused by the rise in Ca_i From our Fluo-3 measurements it appears that the latency of the Ca²⁺ increase is by 3–4 ms longer than the latency of the receptor potential elicited by bright 100-ms light flashes. This result provides no support for the proposal that Ca²⁺ mediates the opening of those membrane channels responsible for the upstroke of the receptor potential.Abbreviations ER endoplasmic reticulum - IP₃ Inositol 1,4,5-trisphosphate - SMC submicrovillar cisternae     

The spectral sensitivity of eye movements in response to light flashes inDaphnia magna

Summary The crustaceanDaphnia magna responds to a flash of light with a ventral rotation of its compound eye; this behavior is termed eye flick. We determined the spectral sensitivity for the threshold of eye flick in response to light flashes having three different spatial characteristics: (1) full-field, extending 180° from dorsal to ventral in the animal's field of view; (2) dorsal, 30° wide and located in the dorsal region of the visual field; (3) ventral, same as dorsal but located ventrally. All three stimuli extended 30° to the right and to the left of the animal's midplane. We found that spectral sensitivity varies with the spatial characteristics of the stimulus. For full-field illumination, the relative sensitivity was maximal at 527 nm and between 365 nm and 400 nm, with a significant local minimum at 420 nm. For the dorsal stimulus, the relative sensitivity was greatest at 400 nm, but also showed local maxima at 440 nm and 517 nm. For the ventral stimulus, the relative sensitivity maxima occurred at the same wavelengths as those for the full-field stimulus. At wavelengths of 570 nm and longer, the responses to both dorsal and ventral stimuli showed lower relative sensitivity than the full-field stimulus. No circadian or other periodic changes in threshold spectral sensitivity were observed under our experimental conditions. Animals which had their nauplius eyes removed by means of laser microsurgery had the same spectral sensitivity to full-field illumination as normal animals. Our results are discussed in terms of our current knowledge of the spectral classes of photoreceptors found in theDaphnia compound eye.     

The effect of light on glycogen turnover in the retina of the intact honeybee drone (Apis mellifera)

Summary The drone retina is composed of two types of cells: the photoreceptors in which no glycogen has been detected by electron microscopy and the glial cells which have abundant glycogen stores. 15 min light stimulation of the retina of intact drones caused a 33% decrease of the glycogen content, which recovered with more prolonged stimulation. Photostimulation of the retina for more than 15 min led to an increase of incorporation of³H-glucose into glycogen. Since apparently both synthesis and degradation increase (when stimulation lasts for more than 15 min) the results demonstrate an increase of glycogen turnover.     

Topography of Ca2+-sequestering endoplasmic reticulum in photoreceptors and pigmented glial cells in the compound eye of the honeybee drone

Summary The endoplasmic reticulum (ER) in the photoreceptors of the honeybee drone, Apis mellifera, is highly differentiated and morphologically more complex than suggested by previous studies. In addition to the prominent voluminous submicrovillar cisternae we describe a submitochondrial ER. It separates the mitochondria-containing periphery from the core of the cell. The cell core contains many fenestrated ER cisternae that are horizontally and periodically arranged. We show that all parts of the ER, except for a tubulovesicular portion but including the nuclear envelope, are continuous; all parts appear to accumulate Ca²⁺ actively and with high affinity. Our results confirm previous suggestions that the submicrovillar ER is the major intracellular Ca²⁺ -store in the photoreceptors. The submitochondrial ER is thought to participate in Ca²⁺-regulation in the mitochondrial microenvironment. Moreover, we describe for the first time an extensive, morphologically complex Ca²⁺-sequestering ER in the pigmented glial cells; it might participate in the regulation of the glycogen metabolism.     

Enhancement of sensitivity in photoreceptors of the honey bee drone by light and by Ca2+

Summary Deeply dark adapted (1 h) photoreceptor cells of the honey bee drone show a light-induced enhancement of sensitivity (facilitation) as an aftereffect of illumination or in the presence of dim backgrounds.The Ca²⁺-dependency of this effect was studied: Reduction of extracellular Ca²⁺ to 0.1 mM decreases the sensitivity of a dark adapted cell, and the light-induced increase in sensitivity due to repetitive, dim, 20 ms test flashes is slower than in normal saline. After a sensitizing conditioning light, the sensitivity drops faster in low-calcium saline. The light-induced enhancement of sensitivity is mimicked by pressure injections of low amounts of Ca²⁺ (Ca²⁺/EGTA-buffers; 0.15 M free Ca²⁺) into a dark adapted cell. Injection of EGTA alone decreases the sensitivity. Injection of a solution containing ca1 mM free Ca²⁺ sequentially decreases and later increases the sensitivity transiently.These results suggest a model in which a progressive increase in intracellular Ca²⁺ concentration by light first increases (facilitates), and, at higher concentrations, decreases (light adapts) the sensitivity of the cells. One possible site of action for this positive and negative feedback control of cell sensitivity by Ca²⁺ is the endoplasmic reticulum.     

The latency of the response of Limulus photoreceptors to inositol trisphosphate lacks the calcium-sensitivity of that to light

Summary The latent period before depolarization of Limulus ventral photoreceptors by light flashes was compared with that following brief, intracellular, pressure-injection of d-myo-inositol 1,4,5 trisphosphate. At temperatures between 18 °C and 22 °C and with an extracellular calcium concentration of 10 mM, the responses of 4 cells to light and to injections of 100 M inositol trisphosphate displayed average latencies of 71 and 56 ms, respectively. The latencies of responses to InsP₃ included an estimated 20 ms dead-time inherent in the injection method. Reducing the temperature lengthened the latency of the response to light (Q₁₀ approximately 3.2 between 7 and 22 °C) more than that to inositol trisphosphate (Q₁₀ approximately 2.3). Bathing the photoreceptors in seawater containing no added calcium and 1 mM of the calcium chelator EGTA greatly increased the latency of the light response at all temperatures, but did not increase the latency of the response to inositol trisphosphate. We conclude that the response to inositol trisphosphate lacks the calcium- and temperature-sensitive latent period which characterizes the response to light. If inositol trisphosphate acts, via the release of stored calcium, to stimulate an intermediate in the visual cascade, then that intermediate would appear to be downstream from the latency-generating mechanism.Abbreviations InsP ₃ D-myo-inositol 1,4,5 trisphosphate - ASW Artificial seawater - Ca _i Cytosolic free calcium ion concentration - Ca ₀ Extracellular calcium ion concentration     

Iodoacetate inhibits the biosynthesis of alanine in glial cells and its utilization in photoreceptors of the honeybee drone (Apis mellifera) retina

The aim of this work was to study the effects of iodoacetate on the metabolism of the honeybee drone retina. In the superfused retina, iodoacetate only at high concentration (3 mmol·1^-1) causes a 77% decrease in the O₂ consumption induced by a flash of light. Chromatographic analysis showed that 3 mmol·1^-1 iodoacetate strongly inhibited glycolysis in the retinal glial cells and consequently suppressed the biosynthesis of alanine, which is the fuel transferred from the glia to the photoreceptors. However, the synthesis of ¹⁴C-alanine from [1-¹⁴C]-pyruvate was not affected by iodoacetate. It was therefore surprising to find that superfusion of the retina with 10 mmol·1^-1 pyruvate had no protective effect on the decrease in O₂ consumption, and that the ¹⁴CO₂ production from [1-¹⁴C]-pyruvate was inhibited 60% by iodoacetate. Also, no protection from the effect of iodoacetate was obtained by adding 10 and 20 mmol·1^-1 alanine in the superfusate, even though the transport of ¹⁴C-alanine in the photoreceptor cells was not significantly affected by 3 mmol·1^-1 iodoacetate. However, exposure to iodoacetate strongly inhibited the production of ¹⁴C-glutamate from ¹⁴C-alanine. In contrast, the transformation of ¹⁴C-proline to ¹⁴C-glutamate was not affected by iodoacetate. Indeed, in the presence of iodoacetate, photostimulation caused a decrease in the total concentration of proline and glutamate. It appears therefore that 3 mmol·1^-1 iodoacetate inhibits not only glycolysis and, consecutively, the formation of alanine, but also its use in the photoreceptors. Possibly a large intracellular store of proline, whose mitochondrial use was not affected, contributed in slowing down the inhibition of O₂-consumption by iodoacetate.Abbreviations DNP dinitrophenol - HPLC high pressure liquid chromatography - IAA iodoacetate - QO ₂ change in oxygen consumption - QO ₂ oxygen consumption - PO ₂ partial pressure of O₂