Role of adiabatic pathways in the photoisomerization of aromatic olefins

An account is given of the research work carried out in the authors’ laboratory on the excited state behaviour of diarylalkenes with the particular aim of investigating which are the structural factors responsible for the change of mechanism from the diabatic to the less common adiabatic pathway. The effects of the configurational and conformational structure and of the medium polarity on the shape of the potential energy surfaces of the lowest singlet and triplet excited states allow a general interpretation of the adiabatic mechanism to be proposed. The results of combined fluorimetric and photochemical measurements (dependence of spectra, quantum yields and lifetimes on λ_exc and temperature) and of the statistical “principal component analysis”, are described with emphasis on some representative cases.     

The effect of flickering U-V light output on the attractiveness of an insect electrocutor trap to the house-fly, Musca domestica

The ultraviolet lamps commonly used in insect electrocutor traps flicker at twice the mains AC frequency. A trap was modified to be powered from a flicker-free (DC) source. When house-flies, Musca domestica L. (Diptera: Muscidae), were released in a test room containing one flickering and one non-flickering trap, 75% of the flies were caught by the trap with the flickering lamps. Mean intensities and emission spectra were identical. The trap with flickering lamps still caught more flies when the intensity of its lamps was lowered to half that of the DC-driven trap. The implications of these results for testing colour preference in attractant lamps are mentioned.

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Zusammenfassung Die ultravioletten Leuchtröhren, die oft in Lichtfallen zur Bekämpfung von Fluginsekten verwendet werden, flimmern bei der doppelten Frequenz des normalen Netzwechselstromes (d.h. 100 oder 120Hz). Dieses Flimmern ist bei den Insekten, die eine hohe Flimmerlichtverschmelzungsfrequenz haben, sichtbar. Das Ziel dieser Untersuchung war, festzustellen, ob die Flimmerfrequenz die Wirksammkeit der Lichtfalle beeinflusst. Eine Rentokil (Modell 143) Lichtfalle wurde umgebaut, damit sie von zwei 12V Autobatterien betrieben werden konnte, um ein flimmerfries Anlockungslicht zu erzeugen. Stubenfliegen wurden in einem 31,8 Kubikmeter grossen Testraum, worin eine nichtflimmernde und eine unmodifizierte, flimmernde Lichtfalle montiert waren, freigelassen. Bei Versuchen, wo die normale Zimmerbeleuchtungsröhren eingeschaltet waren, wurden 75% der Fliegen in der flimmernden Lichtfalle aufgefangenen. Durchschnittswerte für Lichtintensität Beleuchtungsflächen und Ausstrahlungspektrum blieben identisch. Als dieser Versuch im verdunkelten Raum wiederholt wurde, blieben die Verhältnisse der in den beiden Fallen aufgefangenen Fliegen, unverändert. Die Fangrate der Fallen war jedoch im dunklen Raum höher, weil es keine andere für die Fliegen anlockende Lichtquellen gab. Selbst bei der Hälfte der Lichtintensität der von Gleichstrom betriebenen Lichtfalle, wurden 61% der Fliegen in der nichtflimmernden Falle aufgefangen. (Alle Versuchsergebnisse waren statistisch signifikant.) Diese erhöhte Wirksamkeit blieb für beide Geschlechter gleich. Diese Beobachtung stimmt mit den ähnlichen Flimmerfrequenzwerten von männlichen und weiblichen Art Musca überein. Im Fall der Tsetsefliege sind die beiden Geschlechter verschieden flimmerempfindlich, und deswegen würde man Unterschiede in der Reaktion auf flimmernde Lichtfallen erwarten. Von Natur aus werden Fliegen der Art Musca von flimmerden Licht angelockt. Die Konsequenzen dieser Ergebnisse hinsichtlich der Untersuchung der Farbwahl der Anlockungslichtquellen werden in diser Veröfftentlichung erwaähnt.

     

The photobehaviour of Daphnia spp. as a model to explain diel vertical migration in zooplankton

Many pelagic animal species in the marine environment and in lakes migrate to deeper water layers before sunrise and return around sunset. The amplitude of these diel vertical migrations (DVM) varies from several hundreds of metres in the oceans to approx. 5–20 m in lakes. DVM can be studied from a proximate and an ultimate point of view. A proximate analysis is intended to reveal the underlying behavioural mechanism and the factors that cause the daily displacements. The ultimate analysis deals with the adaptive significance of DVM and the driving forces that were responsible for the selection of the traits essential to the behavioural mechanism. The freshwater cladoceran Daphnia is the best studied species and results can be used to model migration behaviour in general. Phototaxis in Daphnia spp., which is defined as a light-oriented swimming towards (positive phototaxis) or away (negative phototaxis) from a light source, is considered the most important mechanism basic to DVM. A distinction has been made between primary phototaxis which occurs when light intensity is constant, and secondary phototaxis which is caused by changes in light intensity. Both types of reaction are superimposed on normal swimming. This swimming of Daphnia spp. consists of alternating upwards and downwards displacements over small distances. An internal oscillator seems to be at the base of these alternations. Primary phototaxis is the result of a dominance of either the upwards or the downwards oscillator phase, and the direction depends on internal and external factors: for example, fish-mediated chemicals or kairomones induce a downwards drift. Adverse environmental factors may produce a persistent primary phototaxis. Rare clones of D. magna have been found that show also persistent positive or negative primary phototaxis and interbreeding of the two types produces intermediate progeny: thus a genetic component seems to be involved. Also secondary phototaxis is superimposed on normal swimming: a continuous increase in light intensity amplifies the downwards oscillator phase and decreases the upwards phase. A threshold must be succeeded which depends on the rate and the duration of the relative change in light intensity. The relation between both is given by the stimulus strength versus stimulus duration curve. An absolute threshold or rheobase exists, defined as the minimum rate of change causing a response if continued for an infinitely long time. DVM in a lake takes place during a period of 1-5-2 h when light changes are higher than the rheobase threshold. Accelerations in the rate of relative increase in light intensity strongly enhance downwards swimming in Daphnia spp. and this enhancement increases with increasing fish kairomone and food concentration. This phenomenon may represent a ‘decision-making mechanism’ to realize the adaptive goal of DVM: at high fish predator densities, thus high kairomone concentrations, and sufficiently high food concentrations, DVM is profitable but not so at low concentrations. Body axis orientation in Daphnia spp. is controlled with regard to light-dark boundaries or contrasts. Under water, contrasts are present at the boundaries of the illuminated circular window which results from the maximum angle of refraction at 48–9° with the normal (Snell's window). Contrasts are fixed by the compound eye and appropriate turning of the body axis orients the daphnid in an upwards or an obliquely downwards direction. A predisposition for a positively or negatively phototactic orientation seems to be the result of a disturbed balance of the two oscillators governing normal swimming. Some investigators have tried to study DVM at a laboratory scale during a 24 h cycle. To imitate nature, properties of a natural water column, such as a large temperature gradient, were compressed into a few cm. With appropriate light intensity changes, vertical distributions looking like DVM were obtained. The results can be explained by phototactic reactions and the artificial nature of the compressed environmental factors but do not compare with DVM in the field. A mechanistic model of DVM based on phototaxis is presented. Both, primary and secondary phototaxis is considered an extension of normal swimming. Using the light intensity changes of dawn and the differential enhancement of kairomones and food concentrations, amplitudes of DVM could be simulated comparable to those in a lake. The most important adaptive significance of DVM is avoidance of visual predators such as juvenile fish. However, in the absence of fish kairomones, small-scale DVMs are often present, which were probably evolved for UV-protection, and are realized by not enhanced phototaxis. In addition, the ‘decision-making mechanism’ was probably evolved as based on the enhanced phototactic reaction to accelerations in the rate of relative changes in light intensity and the presence of fish kairomones.     

Photophysiology of kleptoplasts: photosynthetic use of light by chloroplasts living in animal cells

Kleptoplasty is a remarkable type of photosynthetic association, resulting from the maintenance of functional chloroplasts—the ‘kleptoplasts’—in the tissues of a non-photosynthetic host. It represents a biologically unique condition for chloroplast and photosynthesis functioning, occurring in different phylogenetic lineages, namely dinoflagellates, ciliates, foraminiferans and, most interestingly, a single taxon of metazoans, the sacoglossan sea slugs. In the case of sea slugs, chloroplasts from macroalgae are often maintained as intracellular organelles in cells of these marine gastropods, structurally intact and photosynthetically competent for extended periods of time. Kleptoplasty has long attracted interest owing to the longevity of functional kleptoplasts in the absence of the original algal nucleus and the limited number of proteins encoded by the chloroplast genome. This review updates the state-of-the-art on kleptoplast photophysiology, focusing on the comparative analysis of the responses to light of the chloroplasts when in their original, macroalgal cells, and when sequestered in animal cells and functioning as kleptoplasts. It covers fundamental but ecologically relevant aspects of kleptoplast light responses, such as the occurrence of photoacclimation in hospite, operation of photoprotective processes and susceptibility to photoinhibition. Emphasis is given to host-mediated processes unique to kleptoplastic associations, reviewing current hypotheses on behavioural photoprotection and host-mediated enhancement of photosynthetic performance, and identifying current gaps in sacoglossan kleptoplast photophysiology research.