Verhaltensbiologische und histologische Untersuchungen zur Magnetrezeption bei Hühnerküken (Gallus gallus)

Wie andere Vögel auch, verfügen Hühner über zwei verschiedene Magnetfeldrezeptoren. In der vorliegenden Arbeit werden diese beiden Rezeptoren, vor allem unter dem Aspekt Verhaltensontogenie eingehender untersucht. Meine Ergebnisse werden durch histologische Untersuchungen gestützt. Ich untersuchte zwei Hühnerrassen, einen braunen und einen weißen Legehuhn Stamm. Mit der Standardmethode konnte ich die Befunde der Literatur bestätigen. Zur Untersuchung des Magnetkompasses im Auge, habe ich Hühner darauf trainiert einen roten Tischtennisball, auf den sie geprägt wurden, in einer bestimmten magnetischen Richtung zu suchen. Im unbelohnten“ Test ist das Magnetfeld um 90 Grad gedreht, so dass der magnetische Norden nun im geographischen Osten liegt. Die braunen Hühner benutzen den Magnetkompass zum Lösen der gestellten Aufgabe, die weißen Hühner wählen zufällig eine Richtung. Eine Veränderung der Trainingsmethode, ein Training im gedrehten Magnetfeld und eine „Bestrafung“, haben das Ergebnis verändert. Die weißen Hühner sind nun in der Lage, die magnetisch richtige Richtung zu finden, die braunen Hühner reagieren verängstigt und wählen nur zufällig eine Richtung. Beide Hühnerrassen können also - unter verschiedenen Voraussetzungen - einen magnetischen Kompass für die Orientierung benutzen

Körpermassenrekonstruktion pleistozäner Cerviden in Java (Sammlung von Koenigswald)

Die vorliegende Arbeit umfasst die Rekonstruktion der Körpermasse pleistozäner Cerviden in Java. Zunächst wird ein Rezentmodell erstellt, das den Zusammenhang zwischen Körpermasse und dem jeweiligen Messparameter aufzeigt. Die daraus resultierenden Regressionsgleichungen werden für die Rekonstruktion verwendet. Das fossile dentale und postcraniale Material wird vermessen und die Körpermasse für jedes einzelne Stück rekonstruiert. Die absoluten Werte werden in Körpermassenklassen eingeteilt, um einen Wert unabhängig vom physiologischen Zustand zu erhalten. Die Körpermassen werden, soweit möglich, getrennt nach Gattungen rekonstruiert. Ein Vergleich zeigt, dass es deutliche Unterschiede in der Körpermasse der Gattungen Axis und Muntiacus im Vergleich zu Cervus gibt. Bei der Einteilung in Klassen fällt auf, dass die Klassen 3a (10 kg bis 20 kg) und 3b (20 kg bis 50 kg) ausschließlich von Axis und zu einem kleinen Teil von Muntiacus besetzt werden. Die Klassen 4a und 4b ausschließlich von Cervus. Die einzige von Axis und Cervus besetzte Klasse ist 3c (50 kg bis 100 kg). Anhand dieser aus den Fossilien der Dubois Sammlung gewonnenen Erkenntnisse können nun die Fossilien der von Koenigswald Sammlung beurteilt werden, da diese nicht auf Gattungsniveau bestimmt sind. In beiden Sammlungen liegt der höchste Prozentsatz in der Klasse 3b. Daraus kann man schließen, dass sehr viele Tiere der Gattung Axis vorhanden sind. Die Gattung Cervus hingegen ist nur zu einem recht geringen Prozentsatz vertreten. Diese Verteilung spiegelt sich auch in der Untersuchung der Fundstellen wider. An nur drei der acht untersuchten Fundstellen wurden Tiere der Gattung Cervus gefunden. Ein Vergleich der Körpermassen ergibt keinen signifikanten Unterschied zwischen diesen. Innerhalb der Axis-Hirsche kann man einen Körpermassenunterschied erkennen, der jedoch nicht mit der geographischen Lage der Fundstellen begründet werden kann. Die Untersuchung der Fundstellen aufgrund ihrer Chronologie ergibt keinen signifikanten Unterschied zwischen den Faunenleveln Trinil H.K. und Kedung Brubus. Jedoch ist innerhalb der Faunenlevel eine deutliche Variationsbreite der Körpermasse zu erkennen, welche auf das an den einzelnen Fundstellen herrschende Habitat zurückgeführt werden kann. Die Zuordnung der bisher nicht datierten Fundstellen in die Faunenlevel ist alleine aufgrund der rekonstruierten Körpermassen nicht möglich, jedoch können erste Aussagen über das umgebende Habitat getroffen werden

Interaction of magnetite-based receptors in the beak with the visual system underlying 'fixed direction' responses in birds

Background: European robins, Erithacus rubecula, show two types of directional responses to the magnetic field: (1) compass orientation that is based on radical pair processes and lateralized in favor of the right eye and (2) so-called 'fixed direction' responses that originate in the magnetite-based receptors in the upper beak. Both responses are light-dependent. Lateralization of the 'fixed direction' responses would suggest an interaction between the two magnetoreception systems. Results: Robins were tested with either the right or the left eye covered or with both eyes uncovered for their orientation under different light conditions. With 502 nm turquoise light, the birds showed normal compass orientation, whereas they displayed an easterly 'fixed direction' response under a combination of 502 nm turquoise with 590 nm yellow light. Monocularly right-eyed birds with their left eye covered were oriented just as they were binocularly as controls: under turquoise in their northerly migratory direction, under turquoise-and-yellow towards east. The response of monocularly left-eyed birds differed: under turquoise light, they were disoriented, reflecting a lateralization of the magnetic compass system in favor of the right eye, whereas they continued to head eastward under turquoise-and-yellow light. Conclusion: 'Fixed direction' responses are not lateralized. Hence the interactions between the magnetite-receptors in the beak and the visual system do not seem to involve the magnetoreception system based on radical pair processes, but rather other, non-lateralized components of the visual system

Mathematical analysis of the homing flights of pigeons based on GPS tracks

To analyse the effect of magnetic and olfactory deprivation on the homing flight of pigeons, we released birds from a familiar site with either their upper beak or their nostrils anaesthetized. The tracks were analysed by time lag embedding to calculate the short-term correlation dimension, a variable that reflects the degrees of freedom and thus the number of factors involved in a system. We found that higher natural fluctuations in the earth’s magnetic field characterized by A-indices of 8 and above caused a reduction of the correlation dimension of the control birds. We thus separated the data into two groups according to whether they were recorded on magnetically quiet days or on days with higher magnetic fluctuations. Anaesthetizing the upper beak had no significant effect. Making pigeons anosmic reduced the correlation dimension on magnetically quiet days, but did not cause any reduction on days with higher fluctuations. Altogether, our data suggest an involvement of magnetic cues and olfactory factors during the homing flight and point to a robust, multi-factorial map

The magnetic compass of domestic chickens

In a recent paper, we showed that domestic chickens can be trained to search for a social stimulus in specific magnetic directions. Chickens can hardly fly and have only small home ranges, hence their having a functional magnetic compass may seem rather surprising. Yet considering the natural habitat of their ancestors and their lifestyle until recently, the advantages of a magnetic compass become evident

Magnetoreception in birds : I. immunohistochemical studies concerning the cryptochrome cycle

Cryptochrome 1a, located in the UV/violet-sensitive cones in the avian retina, is discussed as receptor molecule for the magnetic compass of birds. Our previous immunohistochemical studies of chicken retinae with an antiserum that labelled only activated cryptochrome 1a had shown activation of cryptochrome 1a under 373 nm UV, 424 nm blue, 502 nm turquoise and 565 nm green light. Green light, however, does not allow the first step of photoreduction of oxidized cryptochromes to the semiquinone. As the chickens had been kept under ‘white’ light before, we suggested that there was a supply of the semiquinone present at the beginning of the exposure to green light, which could be further reduced and then re-oxidized. To test this hypothesis, we exposed chickens to various wavelengths (1) for 30 min after being kept in daylight, (2) for 30 min after a 30 min pre-exposure to total darkness, and (3) for 1 h after being kept in daylight. In the first case, we found activated cryptochrome 1a under UV, blue, turquoise and green light; in the second two cases we found activated cryptochrome 1a only under UV to turquoise light, where the complete redox cycle of cryptochrome can run, but not under green light. This observation is in agreement with the hypothesis that activated cryptochrome 1a is found as long as there is some of the semiquinone left, but not when the supply is depleted. It supports the idea that the crucial radical pair for magnetoreception is generated during re-oxidation

Magnetoreception : activated cryptochrome 1a concurs with magnetic orientation in birds

The radical pair model proposes that the avian magnetic compass is based on radical pair processes in the eye, with cryptochrome, a flavoprotein, suggested as receptor molecule. Cryptochrome 1a (Cry1a) is localized at the discs of the outer segments of the UV/violet cones of European robins and chickens. Here, we show the activation characteristics of a bird cryptochrome in vivo under natural conditions. We exposed chickens for 30 min to different light regimes and analysed the amount of Cry1a labelled with an antiserum against an epitope at the C-terminus of this protein. The staining after exposure to sunlight and to darkness indicated that the antiserum labels only an illuminated, activated form of Cry1a. Exposure to narrow-bandwidth lights of various wavelengths revealed activated Cry1a at UV, blue and turquoise light. With green and yellow, the amount of activated Cry1a was reduced, and with red, as in the dark, no activated Cry1a was labelled. Activated Cry1a is thus found at all those wavelengths at which birds can orient using their magnetic inclination compass, supporting the role of Cry1a as receptor molecule. The observation that activated Cry1a and well-oriented behaviour occur at 565 nm green light, a wavelength not absorbed by the fully oxidized form of cryptochrome, suggests that a state other than the previously suggested Trp/FAD radical pair formed during photoreduction is crucial for detecting magnetic directions

Seasonally changing cryptochrome 1b expression in the retinal ganglion cells of a migrating passerine bird

Cryptochromes, blue-light absorbing proteins involved in the circadian clock, have been proposed to be the receptor molecules of the avian magnetic compass. In birds, several cryptochromes occur: Cryptochrome 2, Cryptochrome 4 and two splice products of Cryptochrome 1, Cry1a and Cry1b. With an antibody not distinguishing between the two splice products, Cryptochrome 1 had been detected in the retinal ganglion cells of garden warblers during migration. A recent study located Cry1a in the outer segments of UV/V-cones in the retina of domestic chickens and European robins, another migratory species. Here we report the presence of cryptochrome 1b (eCry1b) in retinal ganglion cells and displaced ganglion cells of European Robins, Erithacus rubecula. Immuno histochemistry at the light microscopic and electron microscopic level showed eCry1b in the cell plasma, free in the cytosol as well as bound to membranes. This is supported by immuno blotting. However, this applies only to robins in the migratory state. After the end of the migratory phase, the amount of eCry1b was markedly reduced and hardly detectable. In robins, the amount of eCry1b in the retinal ganglion cells varies with season: it appears to be strongly expressed only during the migratory period when the birds show nocturnal migratory restlessness. Since the avian magnetic compass does not seem to be restricted to the migratory phase, this seasonal variation makes a role of eCry1b in magnetoreception rather unlikely. Rather, it could be involved in physiological processes controlling migratory restlessness and thus enabling birds to perform their nocturnal flights