Motor-maps, navigation and implicit space representation in the hippocampus

Multiple sensory-motor maps located in the brainstem and the cortex are involved in spatial orientation. Guiding movements of eyes, head, neck and arms they provide an approximately linear relation between target distance and motor response. This involves especially the superior colliculus in the brainstem and the parietal cortex. There, the natural frame of reference follows from the retinal representation of the environment. A model of navigation is presented that is based on the modulation of activity in those sensory-motor maps. The actual mechanism chosen was gain-field modulation, a process of multimodal integration that has been demonstrated in the parietal cortex and superior colliculus, and was implemented as attraction to visual cues (colour). Dependent on the metric of the sensory-motor map, the relative attraction to these cues implemented as gain field modulation and their position define a fixed point attractor on the plane for locomotive behaviour. The actual implementation used Kohonen-networks in a variant of reinforcement learning that are well suited to generate such topographically organized sensory-motor maps with roughly linear visuo-motor response characteristics. In the following, it was investigated how such an implicit coding of target positions by gain-field parameters might be represented in the hippocampus formation and under what conditions a direction-invariant space representation can arise from such retinotopic representations of multiple cues. Information about the orientation in the plane—as could be provided by head direction cells—appeared to be necessary for unambiguous space representation in our model in agreement with physiological experiments. With this information, Gauss-shaped “place-cells” could be generated, however, the representation of the spatial environment was repetitive and clustered and single cells were always tuned to the gain-field parameters as well     

The ecology of the avian brain: food-storing memory and the hippocampus

Some species of birds store food, often hoarding several hundreds of seeds over a period of just a few weeks. Field and laboratory studies have demonstrated that food-storing species have an impressive memory and an enlarged region of the brain, the hippocampal region. Lesion experiments have shown that the hippocampus is important in accurate retrieval of stored food. Taken together, these results have led to the hypothesis that the enlarged hippocampus is associated with the memory requirements of retrieving stored food. In this review, we discuss four areas of study: comparative studies of the brain, comparative studies of behaviour, developmental plasticity and seasonal changes in food storing and the hippocampus.     

The ecology of the avian brain: food-storing memory and the hippocampus

Some species of birds store food, often hoarding several hundreds of seeds over a period of just a few weeks. Field and laboratory studies have demonstrated that food-storing species have an impressive memory and an enlarged region of the brain, the hippocampal region. Lesion experiments have shown that the hippocampus is important in accurate retrieval of stored food. Taken together, these results have led to the hypothesis that the enlarged hippocampus is associated with the memory requirements of retrieving stored food. In this review, we discuss four areas of study: comparative studies of the brain, comparative studies of behaviour, developmental plasticity and seasonal changes in food storing and the hippocampus.     

The social transmission of spatial information in homing pigeons

We adapted a technique to explore the social transmission of spatial information in homing pigeons Columba livia. Five demonstrator pigeons were first trained to find a food goal within an indoor arena. This arena consisted of nine lidded cups laid out within a 12x12 grid on the floor. The task was to find the goal cup and flip the lid to obtain the food hidden within. Once the demonstrators had reached criterion the experiment proper began. During stage 1 of the experiment, 10 target birds, which had not previously been trained to find the goal, were introduced to the spatial task either in isolation or paired with a demonstrator. We measured how long they took to complete the task, the number of squares crossed on the grid, and the number of incorrect lids flipped. In stage 2, the target birds were introduced to the arena a second time, by themselves, and we compared the performance of the birds in the two treatments. The pigeons that had been introduced to the task with a demonstrator in stage 1 walked further and made more incorrect choices when searching for the food goal in stage 2 than the pigeons that were introduced to the task alone. This indicates that pigeons learn a spatial, food-finding task more effectively when performing the task alone than when accompanied by a knowledgeable conspecific. We discuss possible reasons for this in the light of previous experiments. Copyright 1999 The Association for the Study of Animal Behaviour.     

Olfaction and homing in pigeons: Nerve-section experiments,critique, hypotheses

Summary At four sites in the cardinal directions from the home loft in about 180 km distance, 135 experimental pigeons (EPs) and 171 control pigeons (CPs) were released. The EPs had been made anosmic by bilateral olfactory nerve section. All birds were completely inexperienced in homing.Homeward orientation was clearly established in the CPs of which 19% returned to the loft. The performances of the EPs were significantly worse in (a) initial orientation, (b) vanishing intervals, (c) distribution of recoveries, and (d) homing success (none of them homed).The EPs still showed the loft-specific preferred compass direction (PCD).The recoveries of the EPs are much more widely scattered in direction than those of the rather well homeward oriented CPs, even if the distances from the release site are the same in both groups. It is concluded that the navigational capability rather than the motivation to fly or to return home is affected by olfactory deprivation. It is further concluded that homing of pigeons depends on olfactory stimuli perceived at the remote sites even at distances as large as 180km.In the data of the anosmic pigeons a non-olfactory component of homeward orientation persists which is much more pronounced on the W-E axis than on the N-S axis. This component alone appears to be insufficient for a return to the loft.Earlier results and conclusions that gave rise to some controversy are critically examined.The present as well as earlier findings are discussed with respect to two alternative hypotheses of olfactory navigation, the mosaic hypothesis (favoured by Papi) and the gradient hypothesis (favoured by the author).Abbreviations EP experimental pigeon(s) - CP control pigeon(s) - CLCP cueless transported control pigeon(s) (see p. 210) - PCD preferred compass direction I gratefully acknowledge the possibility to maintain our pigeon loft in a building that belongs to the Zoological Institute (Prof. M. Lindauer) of the University of Würzburg. I thank B. and K. Brendle, E. Thiele, and K. Wielander for the releasing of pigeons and for other technical assistance.     

Polymorphism within theLDHA gene in the homing and non-homing pigeons

A total of 445 domestic pigeons were genotyped for the lactate dehydrogenase (LDHA) gene. Crude DNA was isolated from blood samples and feathers. Two polymorphic sites were identified in intron 6: one near the splice donor site GT is called site H and the other near the splice acceptor site is called site B. Interestingly, the nucleotide changes of both these sites associate perfectly with the A and B alleles of HaeIII polymorphism: the A allele with nucleotide A of site H and nucleotide T of site B; while the B allele with nucleotide G of site H and nucleotide G of site B. In this study, we have identified the molecular difference between alleles A and B of the pigeon LDHA gene. The difference at site H in intron 6 explains the HaeIII polymorphism. The frequencies of LDHAAB and LDHABB genotypes between the analysed groups differ significantly (P < 0.001); the LDHAA allele was more frequent in the groups of pigeons with elevated homing performance (P < 0.001). The functional difference may be due to the change at site B, the potential splice branch site. Since LDHA activity is associated with the homing ability, it is possible that during the process of selection for the homing ability, the LDHAA allele has been selected, and is more prevalent in the top-racing groups.     

The orientation of homing pigeons in relation to change in sun declination

Summary The sun navigation hypothesis ofMatthews is briefly reviewed with special reference to his sun occlusion experiment which supports this hypothesis. The results of a similar experiment are presented in which 13 young pigeons were kept from sight of the sun during a seven day period including the fall equinox while the sun height at noon decreased 3° 6.7. When the birds were released from a point 93 km. south of their loft they were exposed to a noon sun height equal to that of a point north of their home loft eight days earlier. Nevertheless they showed a northward orientation as did the 10 control birds with no difference in homing performance between the experimental and control groups. These results are not in agreement with those ofMatthews and do not support his sun navigation hypothesis.

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Zusammenfassung Die Sonnennavigations-Hypothese vonMatthews wird kurz besprochen, besonders im Hinblick auf den Warte-Versuch (Sun occlusion experiment), der unter anderem zur Prüfung der Hypothese angestellt wurde. Die Ergebnisse eines im Wilhelmshavener Gebiet angestellten Warteversuchs werden mitgeteilt: 13 Tauben wurden um die Herbst-Tagundnachtgleiche für 7 Tage ohne Sicht der Sonne gehalten, deren Mittagshöhe in dieser Zeit um 3° 6,7 abnahm. Als die Vögel 93 km südlich ihres Heimatorts aufgelassen wurden, befanden sie sich im Gebiet einer Mittags-Sonnenhöhe gleich der, welche vor der Warteperiode etwa 2° nördlich vom Heimatort herrschte. Trotzdem flogen sie gleich den Kontrollen nordwärts ab. Auch im Heimkehrerfolg bestand kein Unterschied zwischen Versuchs-und Kontrolltauben. Diese Ergebnisse stimmen mit den vonMatthews berichteten nicht überein und stützen seine Sonnen-Navigations-Hypothese nicht.

     

Flight effects on plasma glucose, lactate, catecholamines and corticosterone in homing pigeons

Significant increase in the circulating levels of glucose, lactate, adrenaline (A) and noradrenaline (NA) was observed in homing pigeons after a flight of 48 km, lasting 60-80 min. There was, however, no change in plasma corticosterone concentrations. The increase in lactate has been attributed mainly to the activity of the white glycolytic fibres in the flight muscles. The increase in A and NA indicated increased sympathetic activity. It is suggested that the flight-induced increase in A stimulated the release of glucagon which could account for the increase in plasma glucose. The lack of any increase in plasma corticosterone implied that the birds were not under any serious stress during the flight and that these results represent the normal changes that may be expected in pigeons during a free flight of the specified distance and duration.     

Degenerative and regenerative processes in the olfactory system of homing pigeons.

Experimental resection of the olfactory nerve in the homing pigeon induces a total degeneration of the nerve and olfactory epithelium. The orthograde degenerative process starts before the retrograde one. Ten days after resection, new neurons begin to differentiate from the basal cells. The axon forms earlier than the distal dendritic process, and the speed of growth increases slowly. The regenerated axons only reach the bulb in the 5th month. Two months after resection the olfactory epithelium is similar to that of the intact control side. The ultrastructural features of the mucosa and olfactory axons are similar to those of normal ones.     

Effects of flight on blood parameters in homing pigeons

The influence of flight and flight duration on 13 blood parameters was studied in homing pigeons which returned after 2–22 h of flight from release sites 113–620 km away. The haematocrit value decreased from 54.4% in controls to 51.0% in the flown birds. A lowered haematocrit overproportionately improves blood flow. The plasma concentrations of glucose and l(+)-lactate did not differ between experimental and control birds. This is compatible with the idea that carbohydrates are utilized as fuel mainly in the initial phase of flight. Plasma free fatty acid levels were significantly increased during flight and triglyceride concentrations gradually decreased with progressive flight duration. These findings support the view that lipids are the main energy source during flight. Plasma uric acid concentrations were increased two- to fourfold in flown birds. Urea levels gradually rose with flight duration to 400% of controls. Plasma protein concentration was lowered in flown pigeons. These results hint to an increased protein degradation during flight. Na⁺, K⁺, Ca²⁺, and Mg²⁺ levels in the plasma of the flown pigeons were not significantly different from control values. This finding together with the urea/uric acid ratio indicates that no severe dehydration occurred in our pigeons during free-range flight.Abbreviations FA fatty acids - FFA free fatty acids     

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.     

Influence of flight on protein catabolism, especially myofilament breakdown, in homing pigeons

In order to study protein degradation during flight in homing, a high-performance liquid chromatography technique was developed for the quantitative analysis of N^τ-methylhistidine. Secondly, it was necessary to confirm that the excretion of N^τ-methylhistidine correlates with myofilament breakdown in homing pigeons. In these experiments, ten birds were subcutaneously injected with N^τ-[¹⁴C]methylhistidine and the excreta were quantitatively collected for 1 week. Of the 94.5% radioactivity recovered, 87.1% was associated with N^τ-[¹⁴C]methylhistidine and 6.1% with N-acetyl-N^τ-[¹⁴C]methylhistidine. This rapid excretion of unmetabolized N^τ-[¹⁴C]methylhistidine validates the assumption that the amount of N^τ-methylhistidine excreted is a measure of myofilament catabolism in homing pigeons. The influence of endurance flight on protein breakdown was determined after flights from release sites 368–646 km away. Immediately after return, plasma urea and uric acid levels were increased, whereas plasma concentration of N^τ-methylhistidine remained unchanged compared to unflown control birds. Flown pigeons excreted significantly more urea and N^τ-methylhistidine within 24 h and significantly more urea and uric acid within 96 h after flight than unflown controls. Our findings support the hypothesis that in homing pigeons protein catabolism is increased during endurance flight. Elevated N^τ-methylhistidine excretion probably results from repair processes in damaged muscle fibers, including breakdown of myofilaments. Accepted: 29 October 1999     

Metabolic responses of homing pigeons to flight and subsequent recovery

This study examines metabolic changes occurring during short to endurance flights and during subsequent recovery in free-flying pigeons, in particular the change towards lipid utilization with increasing flight duration, lipid supply to the flight muscles, protein utilization and the time needed to metabolically recover. Eight plasma metabolite concentrations were measured in homing pigeons released from sites 20–200 km from the loft (0.3–4.8 h flight duration) just after landing and after keeping birds fasting at rest for 30 and 60 min, respectively, after their return. Birds kept in the loft fasting at rest were used as controls. Plasma free fatty acid and glycerol concentrations increased rapidly with flight duration and leveled off after about 1.5 h. This indicates a marked change towards a high and stable lipid utilization from adipose tissues within 1–2 h of flight. Plasma triglyceride levels and very-low-density lipoproteins were decreased after short flights, but subsequently regained or surpassed fasting levels at rest. This indicates that re-esterification of free fatty acids and delivery as very-low-density lipoproteins to the flight muscles to circumvent constraints of fatty acid supply, as described previously for small passerines, is not as significant in the pigeon which has a much lower mass-specific energy rate. An initial increase in plasma glucose levels and a transient decrease to fasting levels at rest was observed and may reflect the initial use and subsequent exhaustion of glycogen stores. Contrary to other birds and mammals, -hydroxy-butyrate levels increased markedly with flight duration. This may suggest a more important sparing of carbohydrates and protein as gluconeogenic precursors in the pigeon than in other species. Plasma uric acid levels increased linearly up to about 4 h flight duration. This indicates an accelerated protein breakdown during flight which may primarily serve to deliver amino acids as glucogenic precursors and citrate cycle intermediates. With increasing flight duration, the energy sources change from an initial phase based primarily on carbohydrates to a lipid-based endurance phase. It is discussed whether this metabolic change depends on the level of power output or the performed work (energy spent) since the start of flight. During the first hour of recovery, most metabolites reached or approached fasting levels at rest, indicating a marked reduction in lipolysis and protein breakdown. -hydroxy-butyrate levels remained at flight levels and glucose levels increased slightly, indicating a restoration of glycogen stores.Abbreviations VLDL very-low-density lipoproteins - FFA free fatty acids     

Olfaction and the homing ability of pigeons raised in a tropical area in Brazil

Several workers have investigated the effect of anosmia on pigeon navigation in different geographical locations because it has been suggested that homing behavior is based on different cues, such as olfactory cues, the Earth's magnetic field or infrasound, and that in the absence of one cue another would be used. In this situation, no cue is universally indispensable, including olfactory ones. In order to extend such observations to a novel biome, we observed the behaviour of 192 young inexperienced birds raised in southeastern Brazil, a tropical area where olfactory tests had never been run before. The birds were released from eight symmetrically distributed sites 17 to 44 km from the loft. Half of these birds (experimentals) had been made temporarily anosmic by washing their olfactory mucosae with 4% solution of ZnSO4 the day before release, while controls were treated with Ringer solution. The results of release tests showed that anosmia totally impaired the navigational performance of experimental birds, which were unable to home from sites at relatively short distances from home (34-44 km) and whose pooled initial bearings produced a (negative) homeward component not significantly different from 0. Homing performance of controls was significantly better, and their pooled vanishing bearings had a significant homeward component, in spite of much scatter in individual releases. We conclude that pigeon homing in the study area depends on olfactory information, even though local environmental conditions in the interior of the State of Sao Paulo, as in several other parts of the world, do not appear to be as favorable as Italy for the development of efficient olfactory navigation.     

Flight effects on plasma levels of lipid, glucagon and thyroid hormones in homing pigeons

Significant increases in the concentration of plasma glucagon-like immunoreactivity (GLI) and plasma levels of free fatty acids (FFA) and triglycerides (TG) concomitant with decreases in circulating levels of thyroxine (T4) and triiodothyronine (T3) and T3/T4 ratio were observed in homing pigeons, untrained for 3 months, after a flight of 48 km lasting 90-160 min. The increased level of FFA is attributed to glucagon stimulated lipolysis. The elevation of TG levels may be due to altered partitioning and utilization of lipoprotein in adipose tissue and muscle. Reductions in plasma T4, T3 and T3/T4 ratio are probably due to inhibition of T4 secretion and 5'-monodeiodination with possible conversion of T4 to reverse T3 (rT3). These processes may represent a mechanism for regulation of thyroid hormone metabolism during strenuous and extended flight.     

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.