The White-Tailed Eagle, the Apex Predator, Adjusts Diet towards Larger Prey in Suboptimal Territories

Mirski, Paweł; Komar, Ervin

doi:10.3390/d15060747

Open AccessArticle

The White-Tailed Eagle, the Apex Predator, Adjusts Diet towards Larger Prey in Suboptimal Territories

by

Paweł Mirski

^1,*

and

Ervin Komar

²

¹

Faculty of Biology, University of Białystok, Ciołkowskiego 1J, 15-245 Białystok, Poland

²

Pajūrio Tyrimų ir Planavimo Institutas, Baltijos pr. 107, 93223 Klaipėda, Lithuania

^*

Author to whom correspondence should be addressed.

Diversity 2023, 15(6), 747; https://0-doi-org.brum.beds.ac.uk/10.3390/d15060747

Submission received: 30 April 2023 / Revised: 30 May 2023 / Accepted: 5 June 2023 / Published: 6 June 2023

(This article belongs to the Special Issue Conservation and Ecology of Raptors)

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Abstract

:

The White-tailed eagle, an apex predator, is currently recovering its populations across Europe and has already reached high numbers in many countries. This led to the saturation of eagles in optimal habitats and their encroachment on suboptimal ones. We aimed to compare the diet of White-tailed eagles in optimal and suboptimal conditions in northeastern Poland to investigate how population development affected prey composition, which is expected to be lacking in suboptimal eagle territories. We have monitored eagle nests with trail cameras to investigate their diet objectively and precisely. In order to compare territories of different quality, we have conducted modeling of habitat suitability using data on nest locations prior to their saturation. Using recorded photos of the prey, we measured their size and estimated their weight to check if the size and biomass of the prey are comparable between optimal and suboptimal territories. We found that eagles in the latter conditions were not limited by prey biomass but turned to alternative prey and brought larger prey. The alternative prey were large birds such as White storks and Common cranes, but also chicks of other avian predators that were robbed from their nests. Most probably, eagles cope with a lack of optimal prey by ranging farther and exploring non-optimal foraging habitats. We conclude that the diet flexibility of White-tailed eagle enables him to still increase its numbers despite already high densities. Our study also shows that this species might possibly impact the White stork population, as seen in the case of the Black stork and some seabird species.

Keywords:

Haliaaetus albicilla; alternative prey; habitat suitability; superpredation; trail cameras

1. Introduction

The White-tailed eagle, Haliaeetus albicilla, has recovered in Europe in many countries [1,2]. Locally, its numbers increased threefold in the beginning of the XXI century and are still growing [3]. In some European countries, despite the fact that it has already reached high numbers, it is still the most common species among birds of prey [4]. The increase in predator population numbers has to be supported by high availability of preferred prey or high plasticity in switching prey [5,6]. In the breeding season, White-tailed eagles are known to prey on a variety of medium and large prey, most frequently fish and waterfowl, with fish being more prevalent in inland areas and waterfowl being more prevalent in coastal areas [7,8,9,10]. In the breeding season, mammals usually form an accessory prey, but sometimes a significant one, like in the case of Scotland [11].

Given that the White-tailed eagle is an apex predator, the high increase in its density might affect its prey, but prey availability may also limit population growth and therefore force it to shift towards alternative prey. The first was mainly shown by the direct, negative impact that eagles made on seabirds: Eider Somateria mollissima [12] and Great cormorant Phalacrocorax carbo [13], but also less directly on Black stork Ciconia nigra in the inland [14]. The second has so far been investigated mainly by changes in diet composition during population development (increase in eagle density) [15,16]. In Lithuania, the frequency of alternative prey (i.e., terrestrial birds and mammals) and dietary niche breadth did not increase between 2005 and 2018, and authors concluded that White-tailed eagles did not rely more on alternative prey in the course of population development [16]. In Finland, between 1985 and 2010, a dietary shift was observed in which the proportion of birds increased but that of fish and mammals decreased [15]. However, revealing how the largest avian predator in Europe copes with their high food demands in the light of increasing competition and saturation of optimal habitats is still an open question. To answer it, we should quantify habitat suitability and investigate diet separately in optimal and suboptimal habitats. Heuck et al. [17] found that due to population growth, White-tailed eagles started to inhabit suboptimal habitats. In such sites, the area of suitable foraging habitat was smaller, and eagles experienced lower breeding success and a lower average number of chicks. Most probably, food availability is the link between worse foraging conditions and lower fitness in pairs in suboptimal habitats.

We have investigated the diet of White-tailed eagles with the use of trail cameras, mounted in eagles’ nests to check if the prey composition differs between optimal and suboptimal habitats in the still-developing population of northeastern Poland. Territory quality was distinguished with habitat suitability modeling. We expected that in suboptimal territories, eagles will: (1) switch to alternative prey and therefore explore a wider set of prey species, compared to eagles in optimal ones, with better access to abundant and optimal-size prey; (2) compensate for a shortage of prey by hunting on larger animals; and (3) suffer from a food shortage, which will result in less food biomass brought to the nest, a lesser frequency of prey deliveries (because of a lower abundance of prey), and smaller broods. Additionally, by studying the diet of White-tailed eagles during the population expansion, we hoped to contribute to the ongoing debate on this species impact on other rare and protected species [15,18,19].

2. Materials and Methods

2.1. Study Area

The study was carried out in the Podlasie region, a part of northeastern Poland with a continental climate. The region is characterized by mosaic farmland, a few large forest complexes, and marshy river valleys. The terrain is moderately flat but shaped to some extent by glacial events. In the studied part of the region (North Podlasie Lowland), there are almost no natural lakes, but only fish ponds of small and moderate size and important river valleys of Biebrza and Narew, where high numbers of waterfowl stop at spring migration and also breed.

2.2. Habitat Suitability Models

To model habitat suitability in the studied area for the White-tailed eagle, we used data on 29 nest locations (1 nest per territory) (Figure S1) that were occupied in the studied region in the first place, up to 2010. Under the assumption that they should represent the best habitats before the population developed and saturated, if there were more nests per territory, we included only the one occupied in 2010 or the one closest to this date.

As the species is associated with river valleys, waterbodies, and large wetlands, we prepared six raster variables in QGIS 3. Four were based on a detailed vector dataset of hydrological features downloaded from the Hydrological Map of Poland dataset (Polish Geological Institute, available through https://dane.gov.pl/en, accessed 12 February 2023). The vector dataset was transformed with the “proximity” tool to get the distance to waterbodies, distance to main rivers, distance to (any) water, and distance to wetlands. Furthermore, using rasters (100 m resolution) of water and wetness (downloaded from the Copernicus Land Monitoring service), we have calculated the next two variables: the share of water and the share of wetlands (wetness) per square kilometer around the focal pixel. We used the sum of pixels around the focal one to account for the continuity of a habitat, which is important for such a large apex predator. We used the variance inflation factor (VIF) to check the collinearity between predictors and removed those with a VIF greater than 10. Four predictors remained.

Habitat suitability was modeled in R using the ‘biomod2’ package [20]. We have generated 10 sets of pseudoabsences with numbers three times higher than the number of occurrences. Pseudoabsences were drawn with a “disk” strategy with a minimum distance of 5000 m and a maximum of 20,000 m to presence data (actual nest locations). Models were built using the Random Forest algorithm. The data was divided into training and testing datasets in a 70:30 proportion. Next, we carried out the procedure to estimate the importance of the input variables with 10 permutations. Models were validated based on the Receiver Operation Curve (ROC). Predictors importance was estimated on a 0–1 scale with the ’biomod2’ package and averaged for ten permutations.

2.3. Dietary Data

The diet White-tailed eagles was collected by trail cameras mounted in their nest at the stage of 2- to 4-week-old chicks between 2013 and 2018. Two to four trail cameras were mounted each year, about 1.5–4 m from the nest, pointing directly downwards or from a variable angle, so the nest surface was seen like a plate. In one case, the nest had fallen due to heavy wind; in another, a late chick died without obvious reasons; the trail camera was pointing above the nest; or the memory card failed. Excluding such cases, where material was incomplete, the final dataset covered 12 different nests, recorded at medium and large chick stages as well as after fledgling. We used Ltl Acorn 6210MC trail cameras with 32 GB memory cards and twelve 2500 mAh accumulators, which enabled us to follow the nest from May until October and gather at least over twelve thousand 5 MP resolution photos without replacing the accumulators. Trail cameras were set to take two photos after recording movement during the daytime, and afterwards they went into sleep mode for the next 3 min. Additionally, in the same nests, we have noted prey items according to prey remains found in and under the nests in 2011–2018. However, this was a side task, and we noted the visible prey items but did not count prey based on fish scales, fur, or other small remnants.

The territories of White-tailed eagles monitored with trail cameras were attributed to optimal and suboptimal habitats based on the cut-off value of the Random Forest habitat suitability model that minimized the absolute difference between model sensitivity and specificity. The habitat suitability value under each nest was compared with the cut-off value, and if it was lower, the territory was qualified as suboptimal and optimal if higher.

Prey was identified mostly according to expert knowledge. Most birds and mammals were identified by the authors; some consulted with other ornithologists when needed. Fish were also identified by the authors and checked with experienced anglers (mentioned in the Acknowledgments). Fish biomass was estimated from images by measuring every individual fish’s total length (scale based on bird rings from photos) and comparing it with empirical data describing it [21,22,23,24,25,26,27]. For unidentified species, we assigned a weight of 250 g for a small fish and 400 g for a medium-sized one. Bird and mammal biomasses were estimated according to reported adult average weights and estimated weights (upon growth curves) in the case of juveniles [26,27,28,29,30,31,32]. The average size of unidentified pieces of meat was estimated, representing the mean prey biomass from different prey groups (320 g). Apart from the prey items themselves, the number of prey deliveries per day was noted.

2.4. Data Analysis

The impact of habitat suitability on the diet of White-tailed eagles was tested between territories in optimal and suboptimal habitats. The value of the random forest model of habitat suitability for two habitat suitability groups was tested in R software with the Wilcoxon test to check if the division into optimal and suboptimal habitats is visible and statistically supported. Brood size and diet characteristics were also compared with the Wilcoxon test between two habitat suitability groups. In tested prey groups, we have distinguished other avian predators (birds of prey and owls) to test for superpredation intensity between optimal and suboptimal habitats. Secondly, we distinguished large prey, over 3000 g, therefore beyond the size of fish and waterfowl, that White-tailed eagles are known to feed on regularly.

Prey size (the logarithm of prey weight) was investigated with linear models to explain how it was influenced by territory quality (suboptimal vs. optimal) and brood size (a numerical variable). All analyses were carried out in R 4.1.1.

3. Results

3.1. Habitat Suitability Models

Model ensembles from all Random Forest models yielded high performance (ROC = 0.958). Model sensitivity reached 100%, while specificity reached 82.4%. The cut-off value for the model was estimated to be 0.345 for habitat suitability. This threshold was used to divide the optimal (n = 6) and suboptimal (n = 6) territories of the studied species (Figure 1).

All variables contributed significantly to both models (Table 1). The distance to a waterbody was the best predictor of habitat suitability for the White-tailed eagle, followed by the distance to main rivers and to wetlands (Table 1). The sum of wetlands was still an important predictor but contributed the least.

3.2. Diet Composition

White-tailed eagles in northeastern Poland feed on variable prey, dominated by fish and waterfowl (Table 2). Fish dominated visibly in prey number (74%) and slightly in prey biomass (47%), followed by birds. The latter formed 21% of prey numbers but as much as 41% of prey biomass. Mammals were rarely brought (5%) to the nest, but in larger pieces, and thus contributed 12% of prey biomass.

We found 15 species of fish, representing both artificial fish ponds and natural rivers. The carp, Cyprinus carpio, constituted 55% of all the identified fish species brought to the nest. The average mass of this prey species reached 493 g, with a maximum of 2120 g. Other fish species averaged 439 g, ranging from 71 g to 1100 g. The share of carp in prey numbers and biomass shows the importance of the fish ponds for the species in this lakeless part of the region (north Podlasie Lowland).

White-tailed eagles fed on at least seventeen species of birds and a domestic chicken (Table 2). Waterfowl (ducks, geese, rails, swans, and grebes) constituted exactly half of the identified species. Other waterbirds, such as gulls and terns, added another 7% to the bird prey number. Important alternative prey groups were the large birds, such as White stork Ciconia ciconia and Common crane Grus grus (18% of identified birds), but also chicks of other avian predators that must have been taken from their nests, mostly Common buzzard, but also Long-eared owl (11% of bird prey number). Single adults or juveniles of Common ravens and Tawny owls were also noted.

Mammals were the least frequent but locally important in terms of biomass. Young beavers were probably hunted in the water, but other species were possibly taken as carcasses, some of which were likely roadkill. In many cases, we were not able to identify the mammal species as only a piece of meat with fur was recorded at the nest.

Prey remains found in the nest show a more or less similar variety of prey, but with a lesser diversity of fish and a greater diversity of bird species, especially the waterfowl (Table S1). No signs of superpredation were noted in prey remains. This is because White-tailed eagles predate mostly on chicks, yet without contour feathers, they are eaten entirely and leave no trace. The ratio of main prey groups based on nest remains is completely different (Table S2). Birds dominated (80%) in prey remains, while in diets recorded by trail cameras, they were almost four times less frequent (21%). On the contrary, fish (which are eaten whole) were found only rarely in prey remains (14%), but were dominant in the data investigated from trail cameras (74%). Mammals did not differ much between those two datasets.

3.3. Factors Affecting the White-Tailed Eagle Diet

Proportions of main prey groups did not differ significantly between eagles in optimal and suboptimal territories (Table S3), although the difference in the ratio of mammals was slightly higher in optimal territories (Figure S2) but only close to significant (p = 0.076). Detailed comparisons showed eagles fed much more frequently on carp but much less on Northern pike (Esox lucius) and Common roach (Rutilus rutilus) in suboptimal than optimal territories. In the case of bird prey, eagles preyed on white storks and other avian predators much more frequently in suboptimal territories but rarely (compared to optimal ones) on Eurasioan coots, Fulica atra, and Greylag geese, Anser Anser.

To some extent, White-tailed eagles altered their prey preferences depending on habitat quality. In optimal habitats, they hardly fed on other predators, while they did so relatively frequently in suboptimal habitats (Figure 2a). The ratio of superpredation was significantly higher in prey number and prey biomass in suboptimal habitats than optimal habitats (Table S3). Furthermore, we noticed that eagles in suboptimal habitats often brought large prey, such as storks, cranes, and mammals, to their nests (Figure 2b). This result was not statistically significant, but taking into account the small sample size of nests, we consider it to be close to significant. Lastly, we did not find any difference in prey species richness between optimal and suboptimal territories (Table S3).

3.4. Prey Size

We tested the effects of territory quality and brood size on prey size, prey biomass, and the number of prey deliveries. Brood size did not differ between optimal and suboptimal habitats (p = 0.93), although the only brood of three chicks that successfully fledged was recorded in an optimal territory. We did not find a territory quality impact on daily biomass consumption per nest or the daily number of prey deliveries per nest (Figure 3a,b, Table S3). However, we found that the total biomass brought to the nest was greater in broods with multiple chicks (Figure 3c). The number of prey deliveries seemed slightly lower in solitary broods, but not significantly (Figure 3d).

White-tailed eagles fed on larger birds and fish in suboptimal habitats (Table 3). In the case of mammals, their sizes were smaller in suboptimal habitats, but due to the small sample size, the results were not significant (Figure S3). When raising larger broods, eagles selected larger fish, but the same relationship was not significant in the case of bird prey (Table 3). The effect of territory quality was greater than that of brood size. The models explained almost 10% of the variance in fish size, but only almost 5% in the case of bird prey. Overall, in optimal territories, eagles most often brought prey weighing 500–1000 g to their nest.

4. Discussion

4.1. Diet Differences between Optimal and Suboptimal Habitats

We found that the diet of White-tailed eagles was affected by territory quality, but not all of our predictions were confirmed. Eagles switched to alternative prey, but to a limited extent. Dietary breadth, measured by the number of species that were brought to the nest, did not differ with regard to territory quality. However, eagles reached for alternative prey such as large birds other than waterfowl and robbed the nests of other avian predators, mainly the Common buzzard. The latter was already reported in Lithuania [19], but here we were able to show this prey was clearly more frequently used in suboptimal territories. Secondly, we confirmed that in suboptimal conditions in comparison to optimal ones, eagles will compensate for abundant prey with larger fish and birds (but not mammals). In optimal habitats, the most frequent prey ranged from 500 to 1000 g, but it was much more variable in suboptimal habitats and included a relatively high share of prey over 3000 g. The dominant prey size in optimal habitats corresponded to the ones recorded at Estonian fishponds (optimal foraging habitat), where White-tailed eagles preyed on 300–1050 g fish [33]. Interestingly, in the lakeland adjacent to our study, about 20 years before, eagles were estimated to prey on 514 g of fish and 611 g of birds on average [34]. This confirms that in good-quality habitats (such as large lakes) and before the population saturated, White-tailed eagles foraged on relatively small prey, that was possibly abundant and easy to handle and carry.

Additionally, we found that bigger brood also contributed to selection for larger fish, but to a lesser extent than territory quality. In broods of twins or triplets, the prey biomass was greater than in nests with single chicks, but not the number of prey deliveries, which confirms that eagles compensated for higher food demands with larger prey. Finally, we could not confirm that in suboptimal territories, eagles would suffer from food shortages. The daily biomass and number of prey deliveries, as well as the number of chicks per brood, were similar in optimal and suboptimal habitats.

4.2. Mitigation of Lower-Quality Territories with Larger Prey

In Greece, White-tailed eagles occupying territories of potentially similar quality at neighboring lakes were found to hunt on similar prey species of similar body mass. It suggests that in comparable conditions, eagles select locally optimal prey, also in terms of their size [35]. In our case, where territories differed in their quality, we observed a clear difference in selected prey size. In suboptimal territories, eagles brought larger prey to the nest, while in optimal habitats, the most frequent size of prey was much smaller. It seems that the first had to spend additional energy to find larger prey, handle it, and transport it to the nest. Most likely, it required a much larger area to search for bigger prey, but eagles also had to explore habitats that were different from optimal ones (waterbodies, river valleys). The latter was seen as relatively high numbers of adult white storks, which were possibly hunted over agricultural landscapes and by robbing the nests of other avian predators, which requires penetration of the forest. To prove that White-tailed eagles have to range further to find sufficient food for their offspring, we would need to track them with GPS telemetry devices. We did not have such data for the eagles whose nests were monitored by us with trail cameras, but we had followed another adult male, who occupied suboptimal territory on the edges of Biebrza Valley but had no access to the best foraging sites near the river. During most of the season, he ranged over a small area, but when having chicks, the male flew regularly 25 km to the large waterbody (Mirski, unpublished). A similar case was observed in Lesser spotted eagles, Clanga pomarina, which were also forced to forage exceptionally far from their nest to successfully raise chicks in a situation of insufficient foraging areas [36].

A mechanistic population model showed that the increase in density of White-tailed eagles should affect their breeding performance [15]. However, empirical data from Lithuania pointed out that eagles were not food-limited, nor did their reproduction decrease, despite a high increase in density [3,14]. Compensation of poor territory quality by the increase of home ranges to hunt for larger prey might be the best explanation for why the theoretical model and empirical data did not match in this case.

4.3. The Impact of a Developing Apex Predator Population on Its Prey

The growing population of an apex predator often raises questions about its impact on prey species, both livestock and wild animals. Regarding the first, White-tailed eagles pose only a small or moderate threat [8]. Regarding the second, for some prey species, the pressure from this predator can be significant. Thus far, this has mainly been proven for seabirds such as the Common eider [10] and the Black-legged kittiwake Rissa tridactyla [37], which are top-down controlled by the eagles. It is difficult to assess, though, if the current impact is different from a century ago, before the numbers of this species dropped and recovered again.

There is less proof on the impact of the White-tailed eagle on its prey in inland areas, but a recent study shows that they can rob nests of other predators and the Black stork ([14,17,38], this study, and our own unpublished data). Not only by nest robbing but possibly also by killing adult storks, White-tailed eagles can affect other species, particularly Black storks, by creating a “landscape of fear”, in which storks avoid nesting within a few kilometers of an eagle’s nest. This affects nest occupancy rates and breeding performance in this declining species. Our study shows evidence that the White stork is also directly threatened by White-tailed eagles. We found that 13% of birds brought to the nest were adult storks, some even carrying rings, proving they were mature birds. For a long-lived species like storks, a high surplus mortality rate from predation can be reflected in a significant population decline. Similarly, in the case of predated Common cranes, which were, however, found less often in our study, an even higher ratio of White storks and Common cranes to other prey was found in our opportunistically collected data on prey remains in eagles’ nests (Table S2). However, this dataset is biased towards durable leftovers and can lead to the “demonization” of this apex predator, which, in fact, poses some threat to particular prey species but, in optimal territories, relies mostly on fish and waterfowl.

Supplementary Materials

The following supporting information can be downloaded at: https://0-www-mdpi-com.brum.beds.ac.uk/article/10.3390/d15060747/s1. Table S1. White-tailed eagle diet investigated from prey remains found in different nests or seasons in northeastern Poland in 2011–2018; Table S2. Differences in general prey composition of White-tailed eagles from northeastern Poland, studied by examination of prey remains in their nests (2011–2018) and identification of prey from the photos taken by trail cameras recording nests (2013–2018); Table S3. Results of statistical comparisons between diet characteristics of White-tailed eagles in optimal (n = 6) and suboptimal (n = 6) habitats in northeastern Poland, studied with trail cameras at the nest and tested with the Wilcoxon test; Figure S1. Habitat suitability (Random Forest model) for the White-tailed eagle in northeastern Poland; Figure S2. Proportions of main prey groups in the White-tailed eagle diet in territories of optimal and suboptimal habitats; Figure S3. Prey size of the main prey groups of White-tailed eagles, measured from trail camera images recording their nests in optimal and suboptimal habitats in northeastern Poland; Figure S4. Histograms of 484 prey-size items from White-tailed eagle nests in northeastern Poland, identified and measured from trail camera images in the nests located in optimal and suboptimal habitats.

Author Contributions

Conceptualization, P.M.; methodology, P.M. and E.K.; investigation, P.M. and E.K.; data curation, P.M. and E.K.; writing—original draft preparation, P.M.; writing—review and editing, P.M. and E.K.; visualization, P.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Geographic Society, grant number GEFNE75-13.

Institutional Review Board Statement

The license to enter White-tailed eagle nests and monitor them with trail cameras was granted by the Regional Inspectorate for Environmental Protection in Białystok.

Data Availability Statement

Key data are given in Table 2 and Table S1. Additional data is available upon request.

Acknowledgments

We would like to thank Krzysztof Henel for help in collecting data in Biebrza National Park, Marcin Leszczyński, Tomasz Tumiel, and Grzegorz Grygoruk for help in the fieldwork, Sylwester Aftyka for help in the identification of bird feathers, Marcin Wereszczuk, and Ryszard Szerakowski for their help in fish identification.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Comparison of the Random Forest model of habitat suitability values attributed to optimal and suboptimal territories of White-tailed eagles in northeastern Poland.

Figure 2. Comparison of the share of the two alternative prey groups: other raptors (a) and large prey (b), in the diet of the White-tailed eagles occupying optimal and suboptimal territories in northeastern Poland.

Figure 3. Daily prey biomass and the number of prey deliveries per day, recorded in the nests of White-tailed eagles in northeastern Poland and compared between optimal and suboptimal territories (a,b) and broods with single or multiple chicks (c,d).

Table 1. Habitat suitability predictors and their mean importance in Random Forest models (on a 0–1 scale, averaged for ten models) of White-tailed eagle habitats in northeastern Poland.

Model Predictors:	Mean Variable Importance	SD
distance to the main river	0.2258	0.071
distance to the waterbody	0.4014	0.107
distance to the wetland	0.2084	0.056
sum of wetlands in a 5 km radius	0.1118	0.061

Table 2. Diet composition of White-tailed eagles in northeastern Poland from 2013 to 2018, investigated at 12 nests using trail cameras.

Group	Species	Number	Prey Biomass (g)	Average Species Mass (g)	Share in		Share in Number by Habitat
Group	Species	Number	Prey Biomass (g)	Average Species Mass (g)	Number	Biomass	Optimal	Suboptimal
Fish	Cyprinus carpio	286	140,925	493	38.18%	28.98%	26.8%	46.3%
	Esoxlucius	67	22,057	329	8.95%	4.54%	13.4%	5.8%
	Cyprinidae sp.	47	18,067	384	6.28%	3.72%	5.7%	6.7%
	Tinca tinca	36	10,756	299	4.81%	2.21%	6.7%	3.5%
	Hypophthalmichthys nobilis	14	5386	385	1.87%	1.11%	2.5%	1.4%
	Abramis brama	16	5095	318	2.14%	1.05%	1.9%	2.3%
	Rutilus rutilus	20	3732	187	2.67%	0.77%	5.7%	0.5%
	Ctenopharyngodon idella	5	3300	660	0.67%	0.68%	0%	1.2%
	Carassius carassius	9	3268	363	1.20%	0.67%	1.0%	1.4%
	Lota lota	3	1540	513	0.40%	0.32%	0.6%	0.2%
	Blicca bjoerkna	6	939	157	0.80%	0.19%	0.6%	0.9%
	Perca fluviatilis	7	860	123	0.93%	0.18%	0.6%	1.2%
	Silurus glanis	2	804	402	0.27%	0.17%	0.6%	0.0%
	Oncorhynchus mykiss	2	360	180	0.27%	0.07%	0.0%	0.5%
	Salmonidae	1	125	125	0.13%	0.03%	0.0%	0.2%
	Unidentified fish	35	10,750	307	4.67%	2.21%	2.9%	6.0%
	Group total	556	227,964	326	74.2%	46.9%	69.0%	78.1%
Birds	Ciconia Ciconia (adultus)	22	87,550	3980	2.94%	18.01%	1.6%	3.9%
	Fulica atra	34	24,430	719	4.54%	5.02%	6.1%	3.5%
	Anser anser (pullus)	30	22,410	747	4.01%	4.61%	8.0%	1.2%
	Grus grus (adultus)	4	20,600	5150	0.53%	4.24%	0.6%	0.5%
	Gallus gallus domesticus	7	19,600	2800	0.93%	4.03%	1.0%	0.9%
	Anas platyrhynchos	7	6700	957	0.93%	1.38%	1.3%	0.7%
	Buteo buteo	13	5850	450	1.74%	1.20%	0.0%	3.0%
	Columbasp.	4	1440	360	0.53%	0.30%	0.6%	0.5%
	Corvus cornix	4	1190	298	0.53%	0.24%	1.0%	0.2%
	Corvus corax	1	1100	1100	0.13%	0.23%	0.3%	0.0%
	Chroicocephalus ridibundus	6	780	130	0.80%	0.16%	1.9%	0.0%
	Chlidonias sp.	6	610	102	0.80%	0.13%	1.9%	0.0%
	Cygnus sp. (pullus)	1	600	600	0.13%	0.12%	0.3%	0.0%
	Asio otus	3	445	148	0.40%	0.09%	0.0%	0.7%
	Strix aluco	1	350	350	0.13%	0.07%	0.0%	0.2%
	Tachybaptus ruficollis	1	170	170	0.13%	0.03%	0.0%	0.2%
	Sturnus vulgaris	1	80	80	0.13%	0.02%	0.0%	0.2%
	Turdus sp.	1	70	70	0.13%	0.01%	0.0%	0.2%
	Unidentified birds	15	5900	393	2.00%	1.21%	3.2%	1.2%
	Group total	161	199,875	979	21.5%	41.1%	27.8%	17.1%
Mammals	Lepus europaeus	4	13,000	3250	0.53%	2.67%	0.0%	0.9%
	Castor fiber	2	12,000	6000	0.27%	2.47%	0.0%	0.2%
	Capreolus capreolus	5	11,700	2340	0.67%	2.41%	1.0%	0.5%
	Canis lupus familiaris	1	4000	4000	0.13%	0.82%	0.3%	0.0%
	Sus scrofa/domesticus	1	2500	2500	0.13%	0.51%	0.0%	0.2%
	Martes martes	1	1100	1100	0.13%	0.23%	0.0%	0.2%
	Sus scrofa	1	1000	1000	0.13%	0.21%	0.0%	0.2%
	Unidentified mammals	17	13,110	771	2.27%	2.70%	1.9%	2.5%
	Group total	32	58,410	2620	4.3%	12.01%	3.2%	4.7%
	TOTAL	749	486,249	-	100%	100%	100%	100%

Table 3. Linear models explaining single White-tailed eagles’ prey item mass with territory quality (suboptimal/optimal) and the brood size.

	Bird Prey Mass			Fish Prey Mass
Predictors	Estimates	CI	p	Estimates	CI	p
(Intercept)	6.17	5.60–6.74	<0.001	5.44	5.25–5.63	<0.001
Territory (suboptimal)	0.45	0.07–0.84	0.020	0.29	0.17–0.41	<0.001
Brood size	0.15	−0.09–0.39	0.216	0.18	0.09–0.27	<0.001
Observations	131			340
R²/R² adjusted	0.043/0.028			0.094/0.089

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Mirski, P.; Komar, E. The White-Tailed Eagle, the Apex Predator, Adjusts Diet towards Larger Prey in Suboptimal Territories. Diversity 2023, 15, 747. https://0-doi-org.brum.beds.ac.uk/10.3390/d15060747

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Mirski P, Komar E. The White-Tailed Eagle, the Apex Predator, Adjusts Diet towards Larger Prey in Suboptimal Territories. Diversity. 2023; 15(6):747. https://0-doi-org.brum.beds.ac.uk/10.3390/d15060747

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Mirski, Paweł, and Ervin Komar. 2023. "The White-Tailed Eagle, the Apex Predator, Adjusts Diet towards Larger Prey in Suboptimal Territories" Diversity 15, no. 6: 747. https://0-doi-org.brum.beds.ac.uk/10.3390/d15060747

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The White-Tailed Eagle, the Apex Predator, Adjusts Diet towards Larger Prey in Suboptimal Territories

Abstract

1. Introduction

2. Materials and Methods

2.1. Study Area

2.2. Habitat Suitability Models

2.3. Dietary Data

2.4. Data Analysis

3. Results

3.1. Habitat Suitability Models

3.2. Diet Composition

3.3. Factors Affecting the White-Tailed Eagle Diet

3.4. Prey Size

4. Discussion

4.1. Diet Differences between Optimal and Suboptimal Habitats

4.2. Mitigation of Lower-Quality Territories with Larger Prey

4.3. The Impact of a Developing Apex Predator Population on Its Prey

Supplementary Materials

Author Contributions

Funding

Institutional Review Board Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

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