Hippocampal participation in the sun compass orientation of phase-shifted homing pigeons

The orientation of phase-shifted control and hippocampal lesioned homing pigeons with previous homing experience was examined to investigate the possible participation of the hippocampal formation in sun compass orientation. Hippocampal lesioned pigeons displayed appropriate shifts in orientation indicating that such birds possess a functional sun compass that is used for orientation. However, their shift in orientation was consistently larger than in control pigeons revealing a difference in orientation never observed in pigeons that have not undergone a phase shift. Although alternative interpretations exist, the data suggest the intriguing possibility that following a change in the light-dark cycle, the hippocampal formation participates in the re-entrainment of a circadian rhythm that regulates sun compass orientation.     

Perceptual Strategies of Pigeons to Detect a Rotational Centre—A Hint for Star Compass Learning?

Birds can rely on a variety of cues for orientation during migration and homing. Celestial rotation provides the key information for the development of a functioning star and/or sun compass. This celestial compass seems to be the primary reference for calibrating the other orientation systems including the magnetic compass. Thus, detection of the celestial rotational axis is crucial for bird orientation. Here, we use operant conditioning to demonstrate that homing pigeons can principally learn to detect a rotational centre in a rotating dot pattern and we examine their behavioural response strategies in a series of experiments. Initially, most pigeons applied a strategy based on local stimulus information such as movement characteristics of single dots. One pigeon seemed to immediately ignore eccentric stationary dots. After special training, all pigeons could shift their attention to more global cues, which implies that pigeons can learn the concept of a rotational axis. In our experiments, the ability to precisely locate the rotational centre was strongly dependent on the rotational velocity of the dot pattern and it crashed at velocities that were still much faster than natural celestial rotation. We therefore suggest that the axis of the very slow, natural, celestial rotation could be perceived by birds through the movement itself, but that a time-delayed pattern comparison should also be considered as a very likely alternative strategy.     

生物磁学在鸟类定向研究中的进展

地球上广泛存在的地磁场能够为导航提供可靠的信息,因此很多鸟类在迁徙和归巢过程中都使用地磁信息来保证航行方向的正确,在迁徙的鸟类中已经发现有18种是利用地磁罗盘进行定向和导航的。本文从鸟类使用的磁罗盘、航行地图以及磁感应机制等几方面阐述了目前在鸟类生物磁学方面的研究进展。     

Changes in the short-term deflector loft effect are linked to the sun compass of homing pigeons

Despite being the most studied of all avian orientation systems, important questions still remain about the sun compass of homing pigeons, Columba livia. White it is well-documented that the sun compass is usually learned by young pigeons during the first 10–12 weeks of life, the mechanism by which it is calibrated to adjust for seasonal changes in the sun's azimuth is not known with certainty. Previous experiments using short-term deflector loft pigeons indicated that the sun compass may be calibrated by referencing celestial polarization patterns. The present paper describes important measurable changes in the previously reported orientation behaviour of short-term deflector loft birds, and suggests a correlation between these changes and the presence of a massive upper-atmospheric dust cloud of volcanic origin which significantly altered natural skylight polarization patterns in 1982 and 1983. Moreover, it is shown that when the short-term effect was absent (at times when data from previous years suggested it should be present), the birds were also not using sun compass orientation, as demonstrated by their failure to show the standard ‘clockshift’ response to a 6-h fast shift of their internal clocks. These results support the hypothesis that reflected light cues, rather than odours, are the basis of the deflector loft effect in pigeon homing.     

The osmotic magnetometer: a new model for magnetite-based magnetoreceptors in animals

Homing pigeons and migratory birds are well known examples for animals that use the geomagnetic field for their orientation. Yet, neither the underlying receptor mechanism nor the magnetoreceptor itself is known. Recently, an innervated structure containing clusters of magnetite nanocrystals was identified in the upper beak skin of the homing pigeon. Here we show theoretically that such a cluster has a magnetic-field-dependent shape, even in fields as weak as the Earth's magnetic field; by converting magnetic stimuli into mechanical strain, the clusters can be assumed as primary units of magnetoperception in homing pigeons. Since the orientation of the strain ellipsoid indicates the direction of the external magnetic field, a cluster of magnetite nanocrystals also has the potential to serve as the basis of the so-called inclination compass of migratory birds. It is quantitatively demonstrated that the magnetic-field-induced shape change of a cluster can be amplified as well as counterbalanced by means of osmotic pressure regulation, which offers an elegant possibility to determine the magnetic field strength just by measuring changes in concentration. Received: 18 May 1998 / Revised version: 11 February 1999 / Accepted: 11 February 1999     

Brieftauben

Homing pigeons Homing pigeons are well known for their excellent homing abilities which allow them to return to their lofts from unknown releasing sites more than hundreds of kilometres away. Several orientation mechanisms – sun compass, earth's magnetic field, olfactory cues, visual cues – are known to be involved in homing performance as well as parameters such as motivation and experience. New technology give an insight in their homing behaviour and track preferences and it is shown that homing pigeons physiology and neurobiology seem to be functionally adapted to homing. Pigeons races are still common and it is shown how the pigeon breeder tries to maximize the success of his pigeons.     

Avian navigation: from historical to modern concepts

Studies on avian navigation began at the end of the 19th century with testing various hypotheses, followed by large-scale displacement experiments to assess the capacity of the birds' navigational abilities. In the 1950s, the first theoretical concepts were published. Kramer proposed his ‘Map-and-Compass’ model, assuming that birds establish the direction to a distant goal with the help of an external reference, a compass. The model describes homing as a two-step process, with the first step determining the direction to the goal as a compass course and the second step locating this course with the help of a compass. This model was widely accepted when numerous experiments with clock-shifted pigeons demonstrated the use of the sun compass, and thus a general involvement of compass orientation, in homing. The ‘map’ step is assumed to use local site-specific information, which led to the idea of a ‘grid map’ based on environmental gradients. Kramer's model still forms the basis of our present concept on avian homing, yet route integration with the help of an external reference provides an alternative strategy to determine the home course, and the magnetic compass is a second compass mechanism available to birds. These mechanisms are interrelated by ontogenetic learning processes. A two-step process, with the first step providing the compass course and the second step locating this course with the help of a compass, appears to be a common feature of avian navigation tasks, yet the origin of the compass courses differs between tasks according to their nature, with courses acquired by experience for flights within the home range, courses based on navigational processes for returning home, and courses derived from genetically coded information in first-time migrants. Compass orientation thus forms the backbone of the avian navigational system. Copyright 2003 The Association for the Study of Animal Behaviour. Published by Elsevier Science Ltd. All rights reserved.      

Effects of exogenous melatonin on sun-compass orientation of homing pigeons

Experiments were performed to test whether melatonin plays a role in sun-compass orientation of homing pigeons. Birds were kept for a period of time in dim continuous light (LL) or in artificial light-dark (LD) cycles and then released under the sun from unfamiliar sites. Control birds in dim LL were oriented homeward in all cases. Birds with melatonin implants in LD were capable of a correct use of the sun compass at release. Birds with melatonin implants in dim LL, on the contrary, performed very poorly in orientation. The present results demonstrate for the first time that melatonin is involved in the control of the circadian rhythms underlying sun-compass orientation in birds.     

Does Familiarity with the Release Site Influence the Initial Orientation of Homing Pigeons? Experiments with Clock-shifted Birds

Experiments were performed to test whether the familiarity with the release site plays a role in the initial orientation of homing pigeons. Repeated releases of 6 h clock-shifted birds from the same site during the shifting time produced an improvement of their initial orientation: the shift effect decreased progressively. Since in subsequent releases from unfamiliar sites the shift effect reappears, the course correction observed at the familiar site is attributable to local stimuli and not to a general recalibration of the sun compass.     

Does pigeon homing depend on stimuli perceived during displacement?

Summary In order to test whether stimuli perceived during passive displacement are important for the subsequent homing, pigeons were transported in an apparatus designed to prevent them from receiving relevant information: The experimental birds were continuously rotated quite rapidly (1.5 cps, radial acceleration about 4 g); in addition, they were exposed to an artificial magnetic field and supplied with bottled air. Control birds were transported in open-air cages on top of the van with free view to all sides.Five pairs of releases from equal distances in opposite directions were conducted. Experienced birds were released at distances of about 15, 90, and 300 km from the loft, inexperienced birds at distances of about 180km. In each pair of releases both groups of pigeons were significantly homeward oriented. Neither in initial orientation nor in homing performance nor in the distribution of recoveries were the experimental birds inferior to the controls or in any perceptable way different from them.It is concluded that homing of passively displaced pigeons is not primarily based on information gathered during the outward journey.Abbreviations EP experimental pigeon(s) - CP control pigeon(s) The possibility to maintain our pigeon loft in a building that belongs to the Zoological Institute (Prof. M. Lindauer) of the University of Würzburg is gratefully acknowledged.     

Hippocampal ablated homing pigeons show a persistent impairment in the time taken to return home

Summary Homing pigeons were subjected to either hippocampal or control anterior forebrain ablations to examine what role the hippocampus and related structures may play in homing behavior. One year after surgery, the test birds were released from five locations where they had never been before. Both groups were successful in orienting homeward from the release sites, indicating that the hippocampus is not necessary for the neural regulation of a pigeon's map and compass system. Nonetheless, hippocampal ablated pigeons were significantly poorer with respect to the time required to return home, indicating a homing performance impairment. Alternative hypotheses are discussed to explain this result, the most parsimonious being impaired ability on the part of the hippocampal ablated birds to direct a course homeward.     

Homing pigeons develop local route stereotypy

The mechanisms used by homing pigeons (Columba livia) to navigate homeward from distant sites have been well studied, yet the mechanisms underlying navigation within, and mapping of, the local familiar area have been largely neglected. In the local area pigeons pote ntially have access to a powerful navigational aid--a memorized landscape map. Current opinion suggests that landmarks are used only to recognize a familiar start position and that the goalward route is then achieved solely using compass orientation. We used high-resolution global positioning system (GPS) loggers to track homing pigeons as they became progressively familiar with a local homing task. Here, we demonstrate that birds develop highly stereotyped yet individually distinctive routes over the landscape, which remain substantially inefficient. Precise aerial route recapitulation implies close control by localized geocentric cues. Magnetic cues are unlikely to have been used, since recapitulation remains despite magnetic disruption treatment, and olfactory cues would have been positionally unstable under the variable wind conditions, making visual landmarks the most likely cues used.     

The magnetite-based receptors in the beak of birds and their role in avian navigation

Iron-rich structures have been described in the beak of homing pigeons, chickens and several species of migratory birds and interpreted as magnetoreceptors. Here, we will briefly review findings associated with these receptors that throw light on their nature, their function and their role in avian navigation. Electrophysiological recordings from the ophthalmic nerve, behavioral studies and a ZENK-study indicate that the trigeminal system, the nerves innervating the beak, mediate information on magnetic changes, with the electrophysiological study suggesting that these are changes in intensity. Behavioral studies support the involvement of magnetite and the trigeminal system in magnetoreception, but clearly show that the inclination compass normally used by birds represents a separate system. However, if this compass is disrupted by certain light conditions, migrating birds show ‘fixed direction’ responses to the magnetic field, which originate in the receptors in the beak. Together, these findings point out that there are magnetite-based magnetoreceptors located in the upper beak close to the skin. Their natural function appears to be recording magnetic intensity and thus providing one component of the multi-factorial ‘navigational map’ of birds.     

Pigeon Homing: Does Early Experience Determine what Cues are Used to Navigate?

To test the hypothesis that early experience might determine the nature of the cues used to navigate, homing pigeons were made anosmic by nerve section before they could experience the natural odours in the region of the loft. They were allowed to make free flights and trained by flock releases with intact controls. Next they were tested and compared with intact controls as well as birds made temporarily anosmic just before the experiment. Initial orientation and homing performance of the experimental birds were very poor and showed that the pigeons were unable to acquire an alternative mechanism of navigation.     

Staying in plastic containers interferes with the orientation of clock-shifted homing pigeons

Staying in plastic containers ventilated with natural air during transport and while waiting at the release site was found to affect the initial orientation of pigeons, Columba livia f. domestica, that were exposed to a 6-h clock-shift. The deflection from the mean direction of controls was significantly smaller, and the mean vector length was significantly shorter, than that of clock-shifted pigeons transported in conventional wooden cages. This effect was most pronounced when the birds stayed in plastic containers for the first and second time. Nonshifted control birds seemed to be largely unaffected by plastic containers. There was no influence on homing performance, which suggests a transient nature of the effect. Since the clock-shifted birds had access to the same orientational cues as the controls, we suggest that their sun compass was impaired by stress. We discuss general implications of this container effect, particularly in relation to some cases of olfactory deprivation where containers have been used and stress-induced side-effects cannot be excluded. Copyright 1999 The Association for the Study of Animal Behaviour.     

Orientation cues used by migratory birds: A review of cue-conflict experiments

During the late 1960s and early 1970s the accumulating evidence of magnetic orientation forced the conclusion that the orientation of migratory birds and homing pigeons is based upon multiple stimuli. 'Cue-conflict experiments' have provided a powerful means of asking how these directional cues relate one to another. The weight of evidence suggests that in short-term orientation decision making, magnetic cues take precedence over stars, and visual information at sunset overrides both these stimuli. Recent experiments point to polarized skylight patterns as the relevant cue in dusk orientation. Although cue-conflict experiments have now been performed on a diversity of species, generalizations are weakened because of differences in experimental design, in the cues examined and in our ability to manipulate those cues. There remains a need for carefully designed comparative studies.     

Pigeon Homing: The Orientation of Young Birds that had been Prevented from Seeing the Sun

To test whether the sun is an essential factor for the development of a functioning orientation system in birds, a group of young pigeons was raised as ‘No-Sun’-birds. They were not allowed to see the sun, and they were released to fly around their loft only under total overcast. The control group had an equal number of opportunities to fly under overcast plus additional flights under sun. When released as untrained birds under solid cloud cover, the ‘No-Sun’-birds were significantly oriented, whereas the controls were not. Small magnets glued between the wings (north toward the head) reversed the ‘No-Sun’-birds' orientation, indicating they used a magnetic compass. These findings show that the orientation system can develop without information from the sun. Differences in the orientation behavior of the ‘No-Sun’-birds and normally raised young pigeons are discussed.     

Sun compass orientation in seed-caching scrub jays (Aphelocoma coerulescens)

Summary In their natural environment, scrub jays harvest pinyon pine seeds and store them in subterranean caches. In our tests, the birds performed this behavior in an octagonal outdoor aviary with sand-filled cups inserted in the floor. For caching, only 12 such cups in a 90° sector were available, while for the recovery session 4 to 6 days later all 48 cups in the entire aviary were open. In control tests, the birds concentrated their search in the sector where the seeds had been cached. When the internal clock of the birds was shifted 6 h between caching and recovery, they preferentially probed in the adjacent 90° sector. This indicated that they used sun compass information to relocate their caches, largely ignoring visual cues from surrounding landmarks.The dominant role of the sun compass which has a parallel in the orientation of homing pigeons, may reflect a general tendency to prefer compass information in spatial orientation tasks; it is in agreement with the model that birds generally have a directionally oriented view of space.Abbreviations OR Original caches - SH shifted caches     

Das Orientierungssystem der V?gel I. Kompa?mechanismen

Zusammenfassung V?gel stellen den Bezug zum Ziel indirekt über ein externes Referenzsystem her. Der Navigationsproze? besteht deshalb aus zwei Schritten: zun?chst wird die Richtung zum Ziel als Kompa?kurs festgelegt, dann wird dieser Kurs mit Hilfe eines Kompa?mechanismus aufgesucht. Das Magnetfeld der Erde und Himmelsfaktoren werden von den V?gel als Kompa? benutzt. In der vorliegenden Arbeit werden der Magnetkompa?, der Sonnenkompa? und der Sternkompa? der V?gel in ihrer Funktionsweise, ihrer Entstehung und ihrer biologischen Bedeutung vorgestellt. Der Magnetkompa? erwies sich als Inklinationskompa?, der nicht auf der Polarit?t, sondern auf der Neigung der Feldlinien im Raum beruht; er unterscheidet „polw?rts“ und „?quatorw?rts“ statt Nord und Süd. Er ist ein angeborener Mechanismus und wird beim Vogelzug und beim Heimfinden benutzt. Seine eigentliche Bedeutung liegt jedoch darin, da? er ein Referenzsystem bereitstellt, mit dessen Hilfe andere Orientierungsfaktoren zueinander in Beziehung gesetzt werden k?nnen. Der Sonnenkompa? beruht auf Erfahrung; Sonnenazimut, Tageszeit und Richtung werden durch Lernprozesse miteinander verknüpft, wobei der Magnetkompa? als Richtungsreferenzsystem dient. Sobald er verfügbar ist, wird der Sonnenkompa? bei der Orientierung im Heimbereich und beim Heimfinden bevorzugt benutzt; beim Vogelzug spielt er, wahrscheinlich wegen seiner Abh?ngigkeit von der geographischen Breite, kaum eine Rolle. Der Sternkompa? arbeitet ohne Beteiligung der Inneren Uhr; die V?gel leiten Richtungen aus den Konfigurationen der Sterne zueinander ab. Lernprozesse erstellen den Sternkompa? in der Phase vor dem ersten Zug; dabei fungiert die Himmelsrotation als Referenzsystem. Sp?ter, w?hrend des Zuges, übernimmt der Magnetkompa? diese Rolle. Die relative Bedeutung der verschiedenen Kompa?systeme wurde in Versuchen untersucht, bei denen Magnetfeld und Himmelsfaktoren einander widersprechende Richtungs-information gaben. Die erste Reaktion der V?gel war von Art zu Art verschieden; langfristig scheinen sich die V?gel jedoch nach dem Magnetkompa? zu richten. Dabei werden die Himmelsfaktoren umgeeicht, so da? magnetische Information und Himmelsinformation wieder im Einklang stehen. Der Magnetkompa? und die Himmelsfaktoren erg?nzen einander: der Magnetkompa? ersetzt Sonnen- und Sternkompa? bei bedecktem Himmel; die Himmelsfaktoren erleichtern den V?geln das Richtungseinhalten, zu dem der Magnetkompa? offenbar wenig geeignet ist. Magnetfeld und Himmelsfaktoren sollten deshalb als integrierte Komponenten eines multifaktoriellen Systems zur Richtungsorientierung betrachtet werden.

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The orientation system of birds — I. Compass mechanisms

Summary Because of the large distances involved, birds establish contact with their goal indirectly via an external reference. Hence any navigation is a two-step process: in the first step, the direction to the goal is determined as a compass course; in the second step, this course is located with a compass. The geomagnetic field and celestial cues provide birds with compass information. The magnetic compass of birds, the sun compass the star compass and the interactions between the compass mechanisms are described in the present paper. Magnetic compass orientation was first demonstrated by testing night-migrating birds in experimentally altered magnetic fields: the birds changed their directional tendencies according to the deflected North direction. The avian magnetic compass proved to be an inclination compass: it does not use polarity; instead it is based on the axial course of the field lines and their inclination in space, distinguishing “poleward” and “equatorward” rather than North and South. Its functional range is limited to intensities around the local field strength, but this biological window is flexible and can be adjusted to other intensities. The magnetic compass is an innate mechanism that is widely used in bird migration and in homing. Its most important role, however, is that of a basic reference system for calibrating other kinds of orientation cues. Sun compass orientation is demonstrated by clock-shift experiments: Shifting the birds' internal clock causes them to misjudge the position of the sun, thus leading to typical deflections which indicate sun compass use. The analysis of the avian sun compass revealed that it is based only on sun azimuth and the internal clock; the sun's altitude is not involved. The role of the pattern of polarized light associated with the sun is unclear; only at sunset has it been shown to be an important cue for nocturnal migrants, being part of the sun compass. The sun compass is based on experience; sun azimuth, time of day and direction are combined by learning processes during a sensitive period, with the magnetic compass serving as directional reference. When established, the sun compass becomes the preferred compass mechanism for orientation tasks within the home region and homing: in migration, however, its role is minimal, probably because of the changes of the sun's arc with geographic latitude. The star compass was demonstrated in night-migrating birds by projecting the northern stars in different directions in a planetarium. The analysis of the mechanism revealed that the internal clock is not involved; birds derive directions from the spatial relationship of the star configurations. The star compass is also established by experience; the directional reference is first provided by celestial rotation, later, during migration, by the magnetic compass. The relative importance of the various compass mechanisms has been tested in experiments in which celestial and magnetic cues gave conflicting information. The first response of birds to conflicting cues differs considerably between species; after repeated exposures, however, the birds oriented according to magnetic North, indicating a long-term dominance of the magnetic compass. Later tests in the absence of magnetic information showed that celestial cues were not simply ignored, but recalibrated so that they were again in agreement with magnetic cues. The magnetic compass and celestial cues complement each other: the magnetic field ensures orientation under overcast sky; celestial cues facilitate maintaining directions, for which the magnetic compass appears to be ill suited. In view of this, the magnetic field and celestial cues should be regarded as integrated components of a multifactorial system for directional orientation.

     

Orientation of anosmatic pigeons

Summary Test releases performed at five symmetrically arranged sites around the loft, at a distance of 78–99 km from it, showed that 1) anosmatic birds transported without alteration of the earth's magnetic field were completely random-oriented, 2) anosmatic birds transported in a container inside which the intensity of the magnetic field was strongly reduced were unable to orientate homewards and mostly departed according to a preferred compass direction, 3) control birds, which could smell, and were transported without alteration of the magnetic field, were homeward oriented and performed better in homing than both experimental groups. The conclusion is that anosmatic birds are unable to detect home direction at unfamiliar sites and that magnetic stimuli perceived during the outward journey are unable to substitute olfactory cues.Abbreviation PCD preferred compass direction Supported by a grant from the Consiglio Nazionale delle Ricerche