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Summer-autumn feeding ecology of Pied Flycatchers Ficedula hypolueca and Spotted Flycatchers Muscicapa striata: the importance of frugivory in a stopover area in north-west Iberia

Published online by Cambridge University Press:  27 March 2009

ÁNGEL HERNÁNDEZ
ÁNGEL HERNÁNDEZ*
Affiliation:
Department of Agroforestry, University of Valladolid, Avenida de Madrid 44, 34071 Palencia, Spain. e-mail: [email protected]
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Summary

North-west Iberia is a crucial stopover region for European populations of Pied Flycatchers Ficedula hypoleuca and Spotted Flycatchers Muscicapa striata during their summer-autumn migration. Both species are almost completely insectivorous during breeding in Europe and wintering in sub-Saharan Africa, but are known to consume fleshy fruits during summer-autumn migration, though no detailed investigations have been carried out over long periods of time. In this study, the summer-autumn feeding ecology of Pied and Spotted Flycatchers in a stopover area in north-west Spain, with a landscape of hedgerows and irrigated meadows, was studied for five consecutive years (2002–2006). In general, the passage of both flycatcher species was noticeable from mid-August to the end of September, with a peak in the first ten days of September. The two flycatcher species consumed fruits throughout the stopover period in all years, with constant intensity of frugivory in time, though the importance of fruits was almost three times greater in the diet of Pied Flycatchers (c. 30% of feeding acts) than in that of Spotted Flycatchers (c. 10% of feeding acts). Both species preferred Dogwood Cornus sanguinea fruits, but also ate Elder Sambucus nigra berries and Bramble Rubus spp. drupelets. The high level of selection of Dogwood fruits was probably linked to their high lipid content, an essential nutrient for fattening in long-distance migrant passerines. Hedgerows and wood edges in north-west Iberia are rich in fleshy fruits but threatened by intensive farming. Their conservation and restoration are proposed because they seem to be high-quality stopover habitats for partially frugivorous passerines during summer-autumn migration.

Type
Research Articles
Information
Bird Conservation International , Volume 19 , Issue 3 , September 2009 , pp. 224 - 238
Copyright
Copyright © BirdLife International 2009

Introduction

During long-distance migration, the energy demands of migrating land birds increase and patterns of food resource availability vary, producing considerable changes in their general trophic ecology (Hutto Reference Hutto and Cody1985, Parrish Reference Parrish1997, Berthold Reference Berthold2001, Faaborg Reference Faaborg2002, Long and Stouffer Reference Long and Stouffer2003, Newton Reference Newton2008). In this respect, migrating land birds exhibit a high level of foraging and dietary flexibility (Herrera Reference Herrera1978, Gauthreaux Reference Gauthreaux, Farner, King and Parkes1982, Parrish Reference Parrish1997, Reference Parrish2000, McWilliams and Karasov Reference McWilliams and Karasov2001, Salewski and Jones Reference Salewski and Jones2006). It has been verified that bird species traditionally considered to be insectivorous, at least during the breeding period, may include fleshy fruits in their diet during autumn migration due, among other causes, to decreased availability of insects, and abundance and accessibility of fruits that are easily and rapidly digested, thus providing a profitable food source in terms of energy gain and fattening (Hernández Reference Hernández1993, Parrish Reference Parrish1997, Reference Parrish2000, Eggers Reference Eggers2000, Berthold Reference Berthold2001, Faaborg Reference Faaborg2002, Bairlein Reference Bairlein, Berthold, Gwinner and Sonnenschein2003, Ottich and Dierschke Reference Ottich and Dierschke2003, Newton Reference Newton2008).

Pied Flycatchers Ficedula hypoleuca and Spotted Flycatchers Muscicapa striata, two small (13–14 cm long, 14–16 g in weight) Palearctic passerines wintering south of the Sahara, are almost completely insectivorous during the breeding season (Davies Reference Davies1977, Lundberg and Alatalo Reference Lundberg and Alatalo1992, Cramp and Perrins Reference Cramp and Perrins1993) and also in their African winter quarters (Cramp and Perrins Reference Cramp and Perrins1993, Salewski et al. Reference Salewski, Bairlein and Leisler2003, Salewski and Jones Reference Salewski and Jones2006), though there are fewer data available on the latter area. Both species consume fruits during summer-autumn passage, but information comes from very small sample sizes and short periods of time, usually one migration season (Ferns Reference Ferns1975, Bibby and Green Reference Bibby and Green1980, Jordano Reference Jordano1981, Reference Jordano1982, Reference Jordano1987, Debussche and Isenmann Reference Debussche and Isenmann1989, Fuentes Reference Fuentes1994, Hernández Reference Hernández1999). Most (> 75%) of the global population of Pied Flycatchers breed in Europe and then fly en masse towards western Iberia, mainly to the north-west of the peninsula, a crucial stopover and fattening region, before overflying the Sahara apparently non-stop (Bernis Reference Bernis1963, Moreau Reference Moreau1972, Bibby and Green Reference Bibby and Green1980, Veiga Reference Veiga1986, Cramp and Perrins Reference Cramp and Perrins1993, Lundberg Reference Lundberg, Hagemeijer and Blair1997, Hernández Reference Hernández1999, BirdLife International 2004, Flegg Reference Flegg2004, Newton Reference Newton2008). As for the Spotted Flycatcher, approximately half of its global population breeds in Europe, and birds in western Europe then fly south, mainly to stopover sites in north-west Iberia, before going on to Africa where there is no evidence of their overflying the desert but of a gradual progression (Bernis Reference Bernis1963, Moreau Reference Moreau1972, Cramp and Perrins Reference Cramp and Perrins1993, BirdLife International 2004).

Although Pied and Spotted Flycatchers are not endangered species, in recent decades they have undergone small or moderate declines the causes of which are not known, therefore their principal ecological requirements need to be investigated (Tomiałojć Reference Tomiałojć, Tucker and Heath1994, BirdLife International 2004). In this respect, the integration of important stopover sites in migratory land bird conservation plans is necessary, taking into account that their diet changes from insectivorous to partially or mainly frugivorous (Cantos and Tellería Reference Cantos and Tellería1994, Hernández Reference Hernández1999, Parrish Reference Parrish2000, Faaborg Reference Faaborg2002, Sapir et al. Reference Sapir, Abramsky, Shochat and Izhaki2004). Food limitation at stopover sites may affect not only the migratory performance of birds, but also their subsequent reproduction or survival, with potential consequences on population levels (Newton Reference Newton2008). In addition, frugivorous birds have an important role in dispersing seeds (Sekercioglu Reference Sekercioglu2006), and obviously the mobility of birds increases during migration.

In the present study, the summer-autumn feeding ecology of Pied and Spotted Flycatchers at a stopover site in north-west Spain, in a very productive hedgerow habitat with great diversity of fleshy fruits, was examined for five consecutive years. In northern Spain, the edges of woods, hedgerows and other semi-natural habitats, where the highest densities of frugivorous birds are found, generally have greater diversity of fleshy-fruited plants than the better conserved woods (Herrera Reference Herrera and Tellería2004, Hernández Reference Hernández2007). The study area is located in the Castilla y León region, where, according to data collected to the end of 2005, 4 million of the total 9.4 million hectares have been affected by land consolidation, thus increasing the size of agricultural and livestock holdings and reducing the shrub and tree vegetation separating them. Practically all the arable lands have been regrouped and recently areas of pastures and meadows of great environmental value bordering the mountains are also being regrouped, with a very negative effect on hedgerow habitats (Miranda and Rico Reference Miranda, Rico and Gómez-Limón2007). In particular, the study area, lying in a zone of transition to the Cantabrian mountain range and in one of the most impressive landscapes of hedgerows and meadows in the region, has been threatened by land consolidation since 1990 (Hernández Reference Hernández1998), though this has still not occurred.

Specifically, the following aspects were analysed: 1) comparative abundance and density of both flycatcher species; 2) relative importance of insects and fruits in their diet; 3) foraging behaviour used to obtain insects and fruits; and 4) fruit diet and fruit selection. Intra- and inter-annual temporal variations in these aspects and differences between the two flycatcher species were also taken into account. Types of fruits consumed by flycatchers were compared with those consumed by other frugivorous passerines in the same area and on the same study dates.

Methods

Study area

The total area covers 78 ha but only small subareas (18–42 ha) were covered on each sampling day. The study area is located in the Torío river valley (42°43’–42°44’N, 5°30’–5°31’W, 900–1000 m a.s.l.) in the León province, north-west Spain, and forms part of the Supramediterranean bioclimatic stage in the Mediterranean biogeographic region, but is very near the Eurosiberian region. During the study period (2002–2006) and time of year (16 August–30 September), the weather was generally warm (c. 23°C mean maximum and 10°C mean minimum) with intermittent rainfall (c. 20% of days). The principal landscape is composed of hedgerows that separate irrigated meadows, bordered by riparian woodland on one side and Pyrenean Oak Quercus pyrenaica woods on the other. Estimated hedgerow density is 3.3 km per 10 ha.

Eighteen native plant species (shrubs, trees, climbers) bear fleshy fruit in the hedgerows in the study area, taking the multispecific complexes of Rubus brambles and Rosa roses to be one species in each case, but only nine of them have ripe fruit between mid-August and the end of September (Purging Buckthorn Rhamnus catharticus, Brambles Rubus spp. - above all Blackberry R. ulmifolius, and Dewberry R. caesius, Blackthorn Prunus spinosa, Hawthorn Crataegus monogyna, Gooseberry Ribes uva-crispa, Dogwood Cornus sanguinea, White Bryony Bryonia cretica, Elder Sambucus nigra, and Honeysuckle Lonicera periclymenum), Purging Buckthorn and Gooseberry shrubs being very scarce. Although their fruits usually ripen late, ripe Privet Ligustrum vulgare and Guelder Rose Viburnum opulus fruits can sometimes be seen in September during hotter years. The hedgerows vary considerably in height but shrubs and tall trees whose height has not been reduced by pruning are abundant. The width of some hedgerows has been reduced by pruning to stop them from expanding into the meadows, but others are less manipulated and can grow to over 3 m wide.

Data collection

The study area was visited for five consecutive years (2002–2006) to estimate abundance and observe the foraging behaviour and food items consumed by Pied and Spotted Flycatchers in summer-autumn. Sampling was carried out on 48 days in total (per year: 10 days in 2002, 17 in 2003, six in 2004, nine in 2005, and six in 2006; per fortnight: on 18 days during 16–31 August, 16 during 1–15 September, and 14 during 16–30 September) though data on all aspects of the study were not collected every day. At least one visit was made during each fortnight every year. Pied and Spotted Flycatchers do not breed in the study area. Although individuals of both species can be seen in the first fortnight in August and Pied Flycatchers even at the end of July, their passage is not noticeable until the second fortnight in August and continues so until the second fortnight in September, very few being recorded at the beginning of October. Sampling was carried out in the morning, over a mean period of five hours a day between 06h00–12h00 (solar time) when migrating flycatchers show high foraging activity (Ferns Reference Ferns1975, Bibby and Green Reference Bibby and Green1980, pers. obs.).

Data corresponding to 2003–2006 were used to estimate the temporal variation in compared abundance of both flycatcher species. In 2002 their foraging behaviour was studied but the population was not censused; thus 38 days were considered, on each of which a subarea varying in size (18–42 ha) was visited by slowly walking around all the hedgerows and recording all flycatchers seen or heard. Data for 2004–2006 were used to estimate the temporal variation in density (birds per 10 ha), when the same subarea (24 ha) was visited; thus 21 days were considered and abundance figures obtained as above were used; the results for density are shown in 10-day intervals.

To estimate the relative importance of insects and fruits in the diet, and to analyse the foraging techniques of the two flycatcher species, as well as their temporal variations, data corresponding to all sampling days except for one in 2002 and part of another in the same year when data were recorded for consumed fruits but not for captured insects, were used; so 46 days and part of another were considered, when foraging behaviour was studied following each bird until it had carried out a maximum of three feeding acts to avoid pseudoreplication. Sometimes only a single foraging observation was obtained per bird as the flycatchers occasionally switched to a distant perch or perched on a concealed branch (e.g. on the other side of the hedgerow) after the first observation. A record was made of whether the food item was an insect or a fruit, whether the insect was captured on the ground or in flight and whether the fruit was removed while the bird was perched or in flight.

In feeding acts involving insects it was often impossible to verify a successful capture, especially in the case of small insects, so failed attempts were not subtracted and neither were captured insects identified. In feeding acts involving fruits only those that had actually been eaten were considered and it was always possible to identify the fruit species. Flycatchers behaved like dispersers, swallowing each fruit whole. In the case of large composite Rubus bramble fruits, they ate an individual drupelet during each feeding act. The apparent overestimation of the importance of insects (feeding attempts) in comparison with fruits (actually eaten) was probably compensated for by the fact that the search for and capture of insects in thick foliage, particularly tall trees, was underestimated in samplings due to difficulties in observation; however, most of the fruits were usually removed from the outer, middle and lower parts of the shrubs (pers. obs.). So it was assumed that the data set reflected the true diet.

Data corresponding to the 48 sampling days were used to estimate the number of fruits eaten per feeding visit and variation in fruit consumption in the morning (percentages of fruits eaten during the 06h00–08h00, 08h00–10h00, and 10h00–12h00 intervals, out of the total fruits eaten). When a bird ate at least one fruit, this was considered to be a feeding visit.

To estimate differences between the fruit diet of the two flycatcher species and other frugivorous passerines, with regard to plant species involved, data for the 48 sampling days were used, and only feeding visits were considered as there was not enough time during sampling to record the number of fruits eaten per feeding visit by frugivorous birds that were not flycatchers. Data corresponding to feeding visits were also used to estimate the level of selection of fruit species by each bird species using the Jacobs (Reference Jacobs1974) index: S = (v − a)/(v + a − 2va), where v is the proportion of feeding visits by a given bird species to a given plant species, in relation to the total number of feeding visits by that bird species, and a is the proportion of availability of that plant species in relation to total availability of plants with ripe fleshy fruits. This index varies between −1 (maximum negative selection) and 1 (maximum positive selection), with a value of 0 if there is no selection (v = a). Availability of different plant species was estimated using data obtained during eight additional sampling days within the period 28 September–15 October 2004, when approximately 9 km of hedgerows were covered (c. 35% of all the hedgerows evenly distributed in the study area), recording the qualitative occurrence but not the number of individuals of each plant species (shrubs, trees, climbers) in fragments of 2 m long (n = 330 fragments) situated every 25 m (modified from Hernández and Alegre Reference Hernández and Alegre1991). Thus a is the proportion of occurrence of a given plant species in relation to the total occurrences of plant species bearing ripe fruits during the period of bird migration considered (16 August–31 September). S was only calculated for bird species with over 20 recorded feeding visits, and the Guelder Rose was not included in the calculations as its fruits very rarely ripen during this period.

Statistical analysis

The chi-square test (χ2), with Yates correction, was used to compare series of frequencies, and t-test to compare two means. Standard deviation (SD) was estimated as a measurement of dispersion. P < 0.05 was considered statistically significant.

Results

Compared abundance and density in flycatchers

A total of 396 Pied Flycatchers (78 in 2003, 55 in 2004, 187 in 2005, and 76 in 2006) and 398 Spotted Flycatchers (113, 51, 128, and 106, respectively) were recorded (Table 1). In the second fortnight in August in two years Pied Flycatchers represented < 30% and Spotted Flycatchers > 70% of the total number of flycatchers, and in the other two years the two species had similar values (< 60% for both); in the first fortnight in September values were similar for the two species (< 60% for both) every year; in the second fortnight in September, Pied Flycatchers represented > 60% every year and Spotted Flycatchers < 40%, and Pied Flycatchers represented > 70% and Spotted Flycatchers < 30% in three of the study years. Considering all years together, there were significant differences between the two species in fortnightly abundance (χ2 2 = 44.5, P < 0.001), Spotted Flycatchers having greater comparative importance in the second fortnight in August and Pied Flycatchers in the second fortnight in September. The density of both flycatcher species increased progressively in August and continued to do so until the first ten days in September, maximum values being 16.3 Pied Flycatchers per 10 ha in 2005 and 13.3 Spotted Flycatchers per 10 ha in 2006, and then decreased progressively until the end of September (Figure 1).

Figure 1. Pied (PiFly) and Spotted (SpFly) Flycatcher density during the period 2004–2006. The highest recorded value was considered for each 10-day period.

Table 1. Comparative abundance of Pied (PiFly) and Spotted (SpFly) Flycatchers in each fortnight during the period 2003–2006 expressed as the number of individuals detected. 2FAug: second fortnight in August: 16–31 August. 1FSep: first fortnight in September: 1–15 September. 2FSep: second fortnight in September: 16–30 September.

Relative importance of insects and fruits in the diet of flycatchers, and foraging techniques

A total of 536 feeding acts by Pied Flycatchers (170 in 2002, 63 in 2003, 31 in 2004, 180 in 2005, and 92 in 2006) and 698 (157, 149, 43, 171, and 178, respectively) by Spotted Flycatchers were recorded (Table 2). For Pied Flycatchers and considering the three fortnights together, there were significant differences between years in the relative importance of insects and fruits (χ2 4 = 14.0, P < 0.01), although insects were always predominant (66.7–88.0% of feeding acts), and between years in method of capture (χ2 4 = 13.1, P < 0.05), though capture in flight was always more common (76.5–100%). There were no significant differences for this flycatcher species in the remaining comparisons (between years considering the three fortnights together and between fortnights considering the five years together): between fortnights in importance of insects and fruits (71.8–73.6% of insects), between fortnights in the method used to capture insects (in flight 84.2–89.7%), between years in techniques used to obtain fruits (in flight 66.7–90.9%), or between fortnights in techniques used to obtain fruits (in flight 75.9–81.4%) (χ2, P > 0.05 in all cases). There were no significant differences for the Spotted Flycatcher between years or fortnights in any case, insects always being more important than fruits (88.5–93.0% according to the year, 88.6–90.4% according to the fortnight), most insects being captured in flight (94.7–100% according to the year, 97.3–98.9% according to the fortnight), and most fruits being obtained in flight (44.4–100% according to the year, 50.0–77.3% according to the fortnight) (χ2, P > 0.05 in all cases).

Table 2. Insects and fruits in the diet of Pied and Spotted Flycatchers in each fortnight, and foraging techniques, during the period 2002–2006. Insect numbers are feeding attempts on the ground or in flight, and fruit numbers are fruits eaten when the bird was perched or in flight. 2FAug, 1FSep, 2FSep: as in Table 1.

On comparing the two flycatcher species and considering all feeding acts together, the Pied Flycatcher was more frugivorous than the Spotted Flycatcher (27.4% in contrast to 10.2%) (χ2 1 = 60.9, P < 0.001), the Pied Flycatcher caught more insects on the ground than the Spotted Flycatcher (14.1% and 2.4% respectively) (χ2 1 = 49.8, P < 0.001), and the Spotted Flycatcher removed a higher percentage of fruits when perched than the Pied Flycatcher (35.2% and 21.1% respectively) (χ2 1 = 4.29, P < 0.05).

Pied Flycatchers obtained a total of 156 fruits on 130 feeding visits and Spotted Flycatchers 83 fruits on 67 feeding visits. Considering Dogwood alone, which accounted for > 80% of feeding visits to plants by both flycatcher species, there were no significant interspecific differences in the number of fruits taken on each feeding visit (Pied Flycatcher: 1.15 ± 0.36 fruits, range 1–2, n = 108 feeding visits; Spotted Flycatcher: 1.23 ± 0.46 fruits, range 1–3, n = 64 feeding visits; t = −1.37, P > 0.05). Other fruit species were not analysed due to the small sample size.

Fruit consumption by both flycatcher species decreased significantly throughout the morning, considering fruits consumed during the three intervals and expected values at a 1:1:1 ratio (Pied Flycatcher: χ2 2 = 18.8, P < 0.001; Spotted Flycatcher: χ2 2 = 10.4, P < 0.01) (Figure 2). Almost half of the fruits eaten by Pied Flycatchers (69 of 156, 44.2%) and Spotted Flycatchers (40 of 83, 48.2%) were obtained during the 06h00–08h00 interval. There were no significant differences between the two flycatcher species with regard to the number of fruits consumed in each time interval (χ22 = 0.83, P > 0.05).

Figure 2. Variation in fruits consumed by Pied and Spotted Flycatchers throughout the morning during 16 August–30 September considering the period 2002–2006 as a whole. Percentages of the total number of fruits consumed by Pied (n = 156) and Spotted (n = 83) Flycatchers.

Fruit diet and fruit selection

A total of 508 feeding visits by 12 bird species (nine seed dispersers and three seed eaters) to eight fleshy-fruited plant species were recorded, but only seven bird species, all seed dispersers, made more than 20 feeding visits each (European Robin Erithacus rubecula, Common Blackbird Turdus merula, Song Thrush Turdus philomelos, Garden Warbler Sylvia borin, Blackcap Sylvia atricapilla, Pied Flycatcher, and Spotted Flycatcher) (Table 3). The most visited plants were Dogwood, Elder and Brambles. Considering all the years and fortnights together, a significant association was observed between bird species and number of feeding visits to each plant species (χ2 77 = 876.3, P < 0.001), and association was also significant, but close to non-significance, when only the two flycatcher species were compared (χ2 2 = 6.62, P = 0.044). European Robins, and particularly flycatchers, visited mostly Dogwood; Common Blackbirds mainly visited Blackthorn, Hawthorn and Brambles; Song Thrushes visited mostly Hawthorn; and Garden Warblers and Blackcaps mainly visited Elder. Apart from Dogwood (83.1% of feeding visits by Pied Flycatchers and 95.5% by Spotted Flycatchers), flycatchers visited Brambles (13.1% and 3.0% respectively) and Elder (3.8% and 1.5% respectively). In a more detailed analysis for flycatcher species, there were no significant differences between years (considering the three fortnights together) or between fortnights (considering the five years together) in the number of feeding visits to each plant, for either bird species (χ2, P > 0.05 in all cases).

Table 3. Number of feeding visits by frugivorous birds to fleshy-fruited plants in each fortnight during the period 2002–2006. During each feeding visit the bird ate at least one fruit. SD: seed disperser. SE: seed eater. 2FAug, 1FSep, 2FSep: as in Table 1.

In the sampling of hedgerow plants, 27 species were detected, considering the multispecific complexes of Rubus brambles, Rosa roses, Populus poplars, and Salix willows to be a single species in each case, and 18 of these produced fleshy fruits. A total of 741 occurrences were recorded on the seven plant species which regularly offer ripe fruits between mid August and the end of September, Brambles (294 occurrences, 39.7%, a = 0.397), Blackthorn (140 occurrences, 18.9%, a = 0.189), Hawthorn (126 occurrences, 17.0%, a = 0.170), and Dogwood (125 occurrences, 16.9%, a = 0.169) being the most predominant (Table 4). Pied and Spotted Flycatchers selected Dogwood very positively (S > 0.9), and Elder was positively selected by Pied Flycatchers (S = 0.42) and visited by Spotted Flycatchers according to availability (S ≈ 0) (Table 4). Both flycatcher species negatively selected Brambles (S < −0.6) and did not make feeding visits to Blackthorn, Hawthorn, White Bryony or Honeysuckle (S = −1).

Table 4. Fruit selection by principal frugivorous bird species (S: Jacobs index) during 16 August–30 September considering the period 2002–2006 as a whole. S varies between −1 (maximum negative selection) and 1 (maximum positive selection), with the value 0 if selection does not occur (plant species visited according to availability). See Table 3 for feeding visits by each bird species to each plant species. Availability of plant species with ripe fleshy fruits is expressed as the proportion of the total number (n = 741) of qualitative occurrences of these species in the sampling units. The body weight in grams for each bird species appears in parentheses.

The plant species most positively selected (S ≤ 0.3) by other bird species were Dogwood by European Robins; Elder and Blackthorn by Common Blackbirds; Hawthorn, Elder and Dogwood by Song Thrushes; and Elder by Garden Warblers and Blackcaps. Dogwood and Elder were the only plant species positively selected or visited according to availability, and not negatively selected, by all the principal frugivorous bird species.

Discussion

Compared abundance and density in flycatchers

Pied and Spotted Flycatchers were summer-autumn migrants in the study area, their passage being noticeable from the last ten days in August and with a density peak in the first ten days of September. Generally, autumn departure of both species begins in Europe as early as the end of July or beginning of August, and in both species autumn migration phenology seems to coincide in the northern and central areas of the continent (Veiga Reference Veiga1986, Cramp and Perrins Reference Cramp and Perrins1993, Flegg Reference Flegg2004). During the study period, the trend was towards greater comparative abundance of Spotted Flycatchers during stopover in the second fortnight in August, and of Pied Flycatchers in the second fortnight in September, with similar abundance in the first fortnight in September, though the review by Tellería et al. (Reference Tellería, Asensio and Díaz1999) for the Iberian peninsula simply indicates that the maximum passage of both species is in September.

There are not enough data on maximum values for flycatcher density in Spain and Portugal during summer-autumn migration to compare with the present study. In different types of forest (Fagus, Quercus, Pinus, Juniperus) in different areas in Spain located more towards the east than the study area, comparatively lower maximum densities were recorded in September (0.3–1.5 Pied Flycatchers and 0.3–3.0 Spotted Flycatchers per 10 ha, Zamora and Camacho Reference Zamora and Camacho1984a, Reference Zamora and Camachob, Obeso Reference Obeso1987, Costa Reference Costa1993), however, in Pinus forests in south-west Spain (Costa Reference Costa1984) and Quercus forests in central Portugal (Bibby and Green Reference Bibby and Green1980) up to 26 and 42 Pied Flycatchers per 10 ha, respectively, were recorded. These variations were probably due to differences in habitat quality and in the greater or shorter distance of the study areas from the main migration route of flycatchers through western Iberia.

Relative importance of insects and fruits in the diet of flycatchers, and foraging techniques

Pied and Spotted Flycatchers consumed fruit throughout the entire passage period in all the study years, with generally constant frugivory intensity over time, although the importance of fruits in their diet was almost three times greater for the Pied Flycatcher (c. 30% of feeding acts) than for the Spotted Flycatcher (c.10%). Some studies on migrating Pied Flycatchers in the French Mediterranean region and in Quercus forests in northern and central Portugal simply indicate occasional fruit consumption at the end of summer (Ferns Reference Ferns1975, Bibby and Green Reference Bibby and Green1980, Debussche and Isenmann Reference Debussche and Isenmann1989), but Jordano (Reference Jordano1981, Reference Jordano1982, Reference Jordano1987) found moderate values for fruit consumption by this species in different habitats in south-west Spain in summer-autumn (c. 20–35% average volume in fecal and regurgitated samples). Although there is less information for the Spotted Flycatcher, in south-west Spain it also seems to be less frugivorous during autumn migration (c. 2–15% average volume in fecal and regurgitated samples; Jordano Reference Jordano1981, Reference Jordano1987) than the Pied Flycatcher.

Pied and Spotted Flycatchers, in particular the latter, with large heads and bills and weak legs, are adapted to seizing large food items including insects and fruits in flight, and during autumn migration aerial foraging increases in stopover areas (almost always > 75% of feeding acts) in comparison with breeding areas (Ferns Reference Ferns1975, Davies Reference Davies1977, Alatalo and Alatalo Reference Alatalo and Alatalo1979, Bibby and Green Reference Bibby and Green1980, Jordano Reference Jordano1981, Lundberg and Alatalo Reference Lundberg and Alatalo1992, Cramp and Perrins Reference Cramp and Perrins1993, Hernández Reference Hernández1999, this study). Both flycatcher species are similar in size and weight, but Pied Flycatchers have a comparatively stubbier bill than Spotted Flycatchers (Cramp and Perrins Reference Cramp and Perrins1993) and this probably contributes to their consuming more fruit.

Migrating Pied and Spotted Flycatchers usually only consume one or two fruits each feeding visit (Hernández Reference Hernández1999, present study), probably because their small body size considerably limits the volume of food ingested, as verified in other studies of very small frugivorous bird species (e.g. Hernández Reference Hernández2003 for the European Robin). Pied and Spotted Flycatchers consumed more fruits very early in the morning, presumably because there were very few large active flying insects available at this time (Hernández Reference Hernández1995a for the study area in summer), but they did not stop eating fruits throughout the morning.

Fruit diet and fruit selection

Differences in the fruit diet composition of bird species were noticeable, and only two fruit species, Dogwood and Elder, were positively selected or visited according to availability by the seven main frugivorous species. Pied and Spotted Flycatchers preferred Dogwood fruits during the entire stopover period every year. Gape width and fruit size are limiting factors of the first order in seed-dispersing birds that normally swallow entire fruits (Jordano Reference Jordano and Fenner2000, Herrera Reference Herrera, Herrera and Pellmyr2002, Alcántara and Rey Reference Alcántara and Rey2003, pers. obs.), so Blackthorn and Hawthorn fruits, with a mean length and width of generally > 10 mm (Herrera Reference Herrera1987, Snow and Snow Reference Snow and Snow1988), were only consumed by larger bird species, with high positive selection of Blackthorn fruits by Common Blackbirds and Hawthorn fruits by Song Thrushes. The other bird species (European Robin, Sylvia warblers and flycatchers) ate fruits from the rest of the plant species with a mean length and width of generally < 8 mm (Herrera Reference Herrera1987, Snow and Snow Reference Snow and Snow1988), or small individual drupelets of Rubus fruits.

Such a high level of selection of Dogwood fruits by both flycatcher species was probably because of their high lipid content (c. 25% of the dry mass of pulp) and energy supply (c. 5 kcal g−1 of dry pulp), much higher than in other fruit species which did not exceed 7% and 4 kcal g−1, respectively, in any case (Debussche et al. Reference Debussche, Cortez and Rimbault1987, Herrera Reference Herrera1987, Snow and Snow Reference Snow and Snow1988). Preference for lipid-rich fruits was also found in other studies on migrating landbirds in Eurasia and North America (Stiles Reference Stiles1993, Reference Stiles and Fenner2000, Izhaki Reference Izhaki, Levey, Silva and Galetti2002), and according to observations in different places in southern France and northern Iberia (Debussche and Isenmann Reference Debussche and Isenmann1989, Fuentes Reference Fuentes1994, Hernández Reference Hernández1999), Dogwood fruits seem to be attractive for migrating Pied Flycatchers. Dogwood grows mostly in the northern half of Iberia, in moist soil in hedgerows and the edges of deciduous forests, its fruits ripen relatively early in summer and production is fairly constant year after year (Guitián et al. Reference Guitián, Guitián and Navarro1996, López Reference López2004). It therefore probably plays an important part in fattening and energy gain in Pied and Spotted Flycatchers on autumn migration. Other fruits with a high lipid content, such as Terebinth Pistacia terebinthus and Lentisc Pistacia lentiscus (> 55% of the dry mass of pulp, Herrera Reference Herrera1987), are also preferred by migrating Pied Flycatchers in typical Mediterranean environments, from southern France to Andalusia (Jordano Reference Jordano1984, Debusssche and Isenmann 1989, Fuentes Reference Fuentes1994). Fruit lipids can play an important role in forming fat reserves in migrating passerines, especially in moderately frugivorous species such as flycatchers that show slow food passage through the digestive tract and thus efficient lipid assimilation (Fuentes Reference Fuentes1994, Berthold Reference Berthold2001, Bairlein Reference Bairlein, Berthold, Gwinner and Sonnenschein2003, Newton Reference Newton2008).

Garden Warblers and a small number of Blackcaps, like flycatchers, were trans-Saharan migrants, with autumn passage through Spain occurring from the second fortnight in August and low to medium fattening in southern Europe (Rodríguez Reference Rodríguez1985, Cramp and Perrins Reference Cramp and Perrins1993, Tellería et al. Reference Tellería, Asensio and Díaz1999). Both species consumed Dogwood fruits according to availability but selected elderberries very positively. Migrating Sylvia warblers and other passerine species are known to prefer elderberries, probably because of their high protein content (c. 18% of the dry mass of pulp, Herrera Reference Herrera1987) and small size, forming large racemes which makes them easily accessible and easy to swallow (Snow and Snow Reference Snow and Snow1988, Boddy Reference Boddy1991, Hernández Reference Hernández1995b, Berthold Reference Berthold2001, Ottich and Dierschke Reference Ottich and Dierschke2003). Body mass gain in migrating birds is fundamentally the result of the combined effect of high energy intake provided by lipids and protein intake, the latter generally being more dependent on insects (Newton Reference Newton2008).

Concluding remarks: migrating flycatchers, fruits and conservation

One hypothesis to partly explain why insectivorous bird species change to a fundamentally or partially frugivorous diet during migration is the lack of, or reduction in, preferred insect resources (‘resource availability hypothesis’) (Parrish Reference Parrish1997, Berthold Reference Berthold2001, Newton Reference Newton2008). In the study area however, the hedgerows and wet meadows are situated very close to the river, and even the edges of nearby oak stands offer maximum availability of insects in summer and very high availability at the onset of autumn (Hernández et al. Reference Hernández, Purroy and Salgado1993, pers. obs.) and this did not stop Pied and Spotted Flycatchers from eating fruits regularly, also at times during the day when flying insects were most active. Favourable places for migrating landbirds are characterised by a prolonged stopover period and high bird density (Veiga Reference Veiga1986 for Pied Flycatchers; Newton Reference Newton2008 for birds in general), as occurred in the study area. Fruits were probably consumed by flycatchers to optimise their net energy uptake for fattening. Currently, the ‘energy assimilation hypothesis’ best explains fruit consumption by migrating passerines, with an energetic advantage and more rapid increase in body mass thanks to omnivory rather than strict insectivory, though a large quantity of fruits needs to be consumed (Parrish Reference Parrish1997, Eggers Reference Eggers2000, Berthold Reference Berthold2001, Bairlein Reference Bairlein, Berthold, Gwinner and Sonnenschein2003, Newton Reference Newton2008). Some fruit species frequently consumed by migrating flycatchers in Iberia, such as Dogwood in the present study, have a high energy content, only slightly lower than that of insects (c. 5 kcal g−1 dry pulp for Dogwood as previously indicated, in comparison with 5.2–6.8 kcal g−1 dry weight for insects, according to Golley Reference Golley1961, Avery Reference Avery1971, Jordano Reference Jordano1981). Fruits are obtained more easily than insects because they are an immobile and predictable food source, concentrated in space and conspicuous. Their low fibre content enables more rapid digestion and high water content reduces the need to drink; all of which are advantageous factors for migrating passerines (Parrish Reference Parrish2000, Berthold Reference Berthold2001, Newton Reference Newton2008).

Nevertheless, further research is necessary to establish whether the mixing of insects and fruit in the diet of migrating flycatchers really constitutes a population phenomenon, or whether only some individuals were specialised in eating fruits because they had previously fed at sites with few insects but abundant fruits on their migration route (C. J. Whelan pers. comm.). According to some physiological studies (Levey and Karasov Reference Levey and Karasov1989, Reference Levey and Karasov1992) and theoretical models based on physiology (Whelan et al. Reference Whelan, Brown, Schmidt, Steele and Willson2000), diet switching and strong specialization can increase the digestive efficiency of birds by optimal adjustment of the retention time of food in the gut.

Afro-Palearctic migrant birds have suffered a general population decrease over the last 35 years, including partially frugivorous passerines such as flycatchers, Garden Warbler, Common Whitethroat Sylvia communis and Common Redstart Phoenicurus phoenicurus, and research is needed on factors operating on passage areas (Berthold et al. Reference Berthold, Fiedler, Schlenker and Querner1998, Sanderson et al. Reference Sanderson, Donald, Pain, Burfield and van Bommel2006). In nonbreeding, migrating landbirds food is a worldwide key factor in habitat and microhabitat selection on the migration route of each species (e.g. Hutto Reference Hutto and Cody1985) and it has been verified that frugivorous birds select fruit-rich stopover sites (Parrish Reference Parrish2000, Sapir et al. Reference Sapir, Abramsky, Shochat and Izhaki2004), which can be created in pastures and fields by planting suitable fruit shrubs and trees (Foster Reference Foster2007). In north-west Iberia, a crucial stopover region for Pied and Spotted Flycatchers, the conservation and restoration of hedgerows and other habitats with abundant fleshy fruits, for example forest edges, are probably useful measures for maintaining the good health of European populations of these birds and other partially frugivorous migrant passerines, in line with the modern conservation strategy for the wider environment (see Tucker and Evans Reference Tucker and Evans1997).

Acknowledgements

This paper is a research contribution of the Ecology and Conservation of Flora and Fauna Group at Valladolid University, Spain. I thank José Luis Robles, Chris Whelan and an anonymous reviewer for their critical reading of the manuscript.

References

Alatalo, R. V. and Alatalo, R. H. (1979) Resource partitioning among a flycatcher guild in Finland. Oikos 23: 4654.CrossRefGoogle Scholar
Alcántara, J. M. and Rey, P. J. (2003) Conflicting selection pressures on seed size: evolutionary ecology of fruit size in a bird-dispersed tree, Olea europaea. J. Evol. Biol. 16: 11681176.CrossRefGoogle Scholar
Avery, R. A. (1971) Estimates of food consumption by the lizard Lacerta vivipara Jacquin. J. Anim. Ecol. 40: 351365.CrossRefGoogle Scholar
Bairlein, F. (2003) Nutritional strategies in migrating birds. Pp. 321332 in Berthold, P., Gwinner, E. and Sonnenschein, E., eds. Avian migration. Berlin: Springer.CrossRefGoogle Scholar
Bernis, F. (1963) Sobre migración de nuestros Passeriformes transaharianos. Ardeola 8: 41119.Google Scholar
Berthold, P. (2001) Bird migration. A general survey. Second edition. Oxford: Oxford University Press.CrossRefGoogle Scholar
Berthold, P., Fiedler, W., Schlenker, R. and Querner, U. (1998) 25-year study of the population development of Central European songbirds: a general decline, most evident in long-distance migrants. Naturwissenschaften 85: 350353.CrossRefGoogle Scholar
Bibby, C. J. and Green, R. E. (1980) Foraging behaviour of migrant pied flycatchers, Ficedula hypoleuca, on temporary territories. J. Anim. Ecol. 49: 507521.CrossRefGoogle Scholar
BirdLife International (2004) Birds in Europe: population estimates, trends and conservation status. Cambridge: BirdLife International.Google Scholar
Boddy, M. (1991) Some aspects of frugivory by bird populations using coastal dune scrub in Lincolnshire. Bird Study 38: 188199.CrossRefGoogle Scholar
Cantos, F. J. and Tellería, J. L. (1994) Stopover fidelity of four migrant warblers in the Iberian Peninsula. J. Avian Biol. 25: 131134.CrossRefGoogle Scholar
Costa, L. (1984) Composición de la comunidad de aves en pinares del Parque Nacional de Doñana (suroeste de España). Doñana Acta Vertebr. 11: 151183.Google Scholar
Costa, L. (1993) Evolución estacional de la avifauna en hayedos de la montaña cantábrica. Ardeola 40: 111.Google Scholar
Cramp, S. and Perrins, C. M., eds. (1993) The birds of the western Palearctic. Vol. 7. Oxford: Oxford University Press.Google Scholar
Davies, N. B. (1977) Prey selection and the search strategy of the spotted flycatcher (Muscicapa striata): a field study on optimal foraging. Anim. Behav. 25: 10161033.CrossRefGoogle Scholar
Debussche, M., Cortez, J. and Rimbault, I. (1987) Variation in fleshy fruit composition in the Mediterranean region: the importance of ripening season, life form, fruit type and geographical distribution. Oikos 49: 244252.CrossRefGoogle Scholar
Debussche, M. and Isenmann, P. (1989) Fleshy fruit characters and the choices of bird and mammal seed dispersers in a Mediterranean region. Oikos 56: 327338.CrossRefGoogle Scholar
Eggers, S. (2000) Compensatory frugivory in migratory Sylvia warblers: geographical responses to season length. J. Avian Biol. 31: 6374.CrossRefGoogle Scholar
Faaborg, J. (2002) Saving migrants birds. Developing strategies for the future. Austin: University of Texas Press.Google Scholar
Ferns, P. N. (1975) Feeding behaviour of autumn passage migrants in north east Portugal. Ringing & Migration 1: 311.CrossRefGoogle Scholar
Flegg, J. (2004) Time to fly. Exploring bird migration. Thetford: British Trust for Ornithology.Google Scholar
Foster, M. S. (2007) The potential of fruit trees to enhance converted habitats for migrating birds in southern Mexico. Bird Conserv. Int. 17: 4561.CrossRefGoogle Scholar
Fuentes, M. (1994) Diets of fruit-eating birds: what are the causes of interspecific differences? Oecologia 97: 134142.CrossRefGoogle ScholarPubMed
Gauthreaux, S. A. Jr. (1982) The ecology and evolution of avian migration systems. Pp. 93168 in Farner, D. S., King, J. R. and Parkes, K. C., eds. Avian Biology. Vol. 6. Orlando: Academic Press.CrossRefGoogle Scholar
Golley, F. B. (1961) Energy values of ecological materials. Ecology 42: 581584.CrossRefGoogle Scholar
Guitián, J., Guitián, P. and Navarro, L. (1996) Fruit set, fruit reduction, and fruiting strategy in Cornus sanguinea (Cornaceae). Am. J. Bot. 83: 744748.CrossRefGoogle Scholar
Hernández, A. (1993) Variación temporal en el consumo de frutos de arraclán (Frangula alnus) por aves en el valle del río Torío (Cordillera Cantábrica, noroeste de España). Ardeola 40: 2126.Google Scholar
Hernández, A. (1995a) Comportamiento de caza del alcaudón dorsirrojo en verano: variación en el método y en la frecuencia de ataques durante el día, y relación con la disponibilidad de presas. Ardeola 42: 9195.Google Scholar
Hernández, A. (1995b) Nota sobre los frutos consumidos por aves dispersantes de semillas en un seto del noroeste de España. Anales Jard. Bot. Madrid 53: 267270.Google Scholar
Hernández, A. (1998) La concentración parcelaria del valle leonés del Torío condena a sus setos. Quercus 151: 4647.Google Scholar
Hernández, A. (1999) Dieta frugívora de los Papamoscas Cerrojillos Ficedula hypoleuca en paso otoñal: revisión y datos inéditos. Butll. GCA 16: 5360.Google Scholar
Hernández, A. (2003) Variations in spindle Euonymus europaeus consumption by frugivorous birds during the fruiting season. Ardeola 50: 171180.Google Scholar
Hernández, A. (2007) Alimentación de aves frugívoras en setos y bordes de bosque del norte de España: importancia de algunas especies de plantas en invierno y primavera. Ecología 21: 145156.Google Scholar
Hernández, A. and Alegre, J. (1991) Estructura de la comunidad de paseriformes en setos de la provincia de León (noroeste de España). Doñana Acta Vertebr. 18: 237250.Google Scholar
Hernández, A., Purroy, F. J. and Salgado, J. M. (1993) Variación estacional, solapamiento interespecífico y selección en la dieta de tres especies simpátricas de alcaudones Lanius spp. Ardeola 40: 143154.Google Scholar
Herrera, C. M. (1978) Ecological correlates of residence and non-residence in a Mediterranean passerine bird community. J. Anim. Ecol. 47: 871890.CrossRefGoogle Scholar
Herrera, C. M. (1987) Vertebrate-dispersed plants of the Iberian Peninsula: a study of fruit characteristics. Ecol. Monogr. 57: 305331.CrossRefGoogle Scholar
Herrera, C. M. (2002) Seed dispersal by vertebrates. Pp. 185208 in Herrera, C. M. and Pellmyr, O., eds. Plant-animal interactions. An evolutionary approach. Oxford: Blackwell Science.Google Scholar
Herrera, C. M. (2004) Ecología de los pájaros frugívoros ibéricos. Pp. 127153 in Tellería, J. L., ed. La ornitología hoy. Madrid: Editorial Complutense-SEO.Google Scholar
Hutto, R. L. (1985) Habitat selection by nonbreeding, migratory land birds. Pp. 455476 in Cody, M. L., ed. Habitat selection in birds. Orlando: Academic Press.Google Scholar
Izhaki, I. (2002) The role of fruit traits in determining fruit removal in east Mediterranean ecosystems. Pp. 161175 in Levey, D. J., Silva, W. R. and Galetti, M., eds. Seed dispersal and frugivory: ecology, evolution and conservation. Wallingford: CABI Publishing.Google Scholar
Jacobs, J. (1974) Quantitative measurement of food selection. A modification of forage ratio and Ivlev's electivity index. Oecologia 14: 413417.CrossRefGoogle ScholarPubMed
Jordano, P. (1981) Alimentación y relaciones tróficas entre los paseriformes en paso otoñal por una localidad de Andalucía central. Doñana Acta Vetrebr. 8: 103124.Google Scholar
Jordano, P (1982) Migrant birds are the main seed dispersers of blackberries in southern Spain. Oikos 38: 183193.CrossRefGoogle Scholar
Jordano, P. (1984) Relaciones entre plantas y aves frugívoras en el matorral mediterráneo del área de Doñana. PhD Thesis. Seville: The University of Seville.Google Scholar
Jordano, P. (1987) Notas sobre la dieta no insectívora de algunos Muscicapidae. Ardeola 34: 8998.Google Scholar
Jordano, P. (2000) Fruits and frugivory. Pp. 125165 in Fenner, M., ed. Seeds. The ecology of regeneration in plant communities. Second edition. Wallingford: CABI Publishing.CrossRefGoogle Scholar
Levey, D. J. and Karasov, W. H. (1989) Digestive responses of temperate birds switched to fruit or insect diets. Auk 106: 675686.Google Scholar
Levey, D. J. and Karasov, W. H. (1992) Digestive modulation in a seasonal frugivore, the American robin (Turdus migratorius). Am. J. Physiol. 262: G711G718.Google Scholar
Long, J. A. and Stouffer, P. C. (2003) Diet and preparation for spring migration in captive Hermit Thrushes (Catharus guttatus). Auk 120: 323330.CrossRefGoogle Scholar
López, G. (2004) Guía de los árboles y arbustos de la Península Ibérica y Baleares. Second edition. Madrid: Mundi-Prensa.Google Scholar
Lundberg, A. (1997) Pied Flycatcher Ficedula hypoleuca. Pp. 620621 in Hagemeijer, E. J. M. and Blair, M. J., eds. The EBCC atlas of European breeding birds: their distribution and abundance. London: Poyser.Google Scholar
Lundberg, A. and Alatalo, R. V. (1992) The Pied Flycatcher. London: Poyser.Google Scholar
McWilliams, S. R. and Karasov, W. H. (2001) Phenotypic flexibility in digestive system structure and function in migratory birds and its ecological significance. Comp. Biochem. Physiol., A 128: 579593.CrossRefGoogle ScholarPubMed
Miranda, B. and Rico, M. (2007) La agricultura de Castilla y León: situación actual y retos de futuro. Pp. 2949 in Gómez-Limón, J. A., ed. El futuro de la agricultura en Castilla y León. Palencia: Centro Tecnológico Agrario y Agroalimentario.Google Scholar
Moreau, R. E. (1972) The Palaearctic-African bird migration systems. London and New York: Academic Press.Google Scholar
Newton, I. (2008) The migration ecology of birds. London: Academic Press.Google Scholar
Obeso, J. R. (1987) Comunidades de passeriformes en bosques mixtos de altitudes medias de la Sierra de Cazorla. Ardeola 34: 3759.Google Scholar
Ottich, I. and Dierschke, V. (2003) Exploitation of resources modulates stopover behaviour of passerine migrants. J. Ornithol. 144: 307316.CrossRefGoogle Scholar
Parrish, J. D. (1997) Patterns of frugivory and energetic condition in Nearctic landbirds during autumn migration. Condor 99: 681697.CrossRefGoogle Scholar
Parrish, J. D. (2000) Behavioral, energetic, and conservation implications of foraging plasticity during migration. Stud. Avian Biol. 20: 5370.Google Scholar
Rodríguez, M. (1985) Weights and fat accumulation of Blackcaps Sylvia atricapilla during migration through southern Spain. Ringing & Migration 6: 3338.CrossRefGoogle Scholar
Salewski, V., Bairlein, F. and Leisler, B. (2003) Niche partitioning of two Palearctic passerine migrants with Afrotropical residents in their West African winter quarters. Behav. Ecol. 14: 493502.CrossRefGoogle Scholar
Salewski, V. and Jones, P. (2006) Palearctic passerines in Afrotropical environments: a review. J. Ornithol. 147: 192201.CrossRefGoogle Scholar
Sanderson, F. J., Donald, P. F., Pain, D. J., Burfield, I. J. and van Bommel, F. P. J. (2006) Long-term population declines in Afro-Palearctic migrant birds. Biol. Conserv. 131: 93105.CrossRefGoogle Scholar
Sapir, N., Abramsky, Z., Shochat, E. and Izhaki, I. (2004) Scale-dependent habitat selection in migratory frugivorous passerines. Naturwissenschaften 91: 544547.CrossRefGoogle ScholarPubMed
Sekercioglu, C. H. (2006) Increasing awareness of avian ecological function. Trends Ecol. Evol. 21: 464471.CrossRefGoogle ScholarPubMed
Snow, B. and Snow, D. (1988) Birds and berries. Calton: Poyser.Google Scholar
Stiles, E. W. (1993) The influence of pulp lipids on fruit preference by birds. Plant Ecol. 107–108: 227235.CrossRefGoogle Scholar
Stiles, E. W. (2000) Animals as seed dispersers. Pp. 111124 in Fenner, M., ed. Seeds. The ecology of regeneration in plant communities. Second edition. Wallingford: CABI Publishing.CrossRefGoogle Scholar
Tellería, J. L., Asensio, B. and Díaz, M. (1999) Aves ibéricas. Vol. 2. Madrid: Reyero.Google Scholar
Tomiałojć, L. (1994) Spotted Flycatcher Muscicapa striata. Pp. 404405 in Tucker, G. M. and Heath, M. F., eds. Birds in Europe: their conservation status. Cambridge: BirdLife International.Google Scholar
Tucker, G. M. and Evans, M. I. (1997) Habitats for birds in Europe: a conservation strategy for the wider environment. Cambridge: BirdLife International.Google Scholar
Veiga, J. P. (1986) Settlement and fat accumulation by migrant Pied Flycatchers in Spain. Ringing & Migration 7: 8598.CrossRefGoogle Scholar
Whelan, C. J., Brown, J. S., Schmidt, K. A., Steele, B. B. and Willson, M. F. (2000) Linking consumer-resource theory and digestive physiology: application to diet shifts. Evol. Ecol. Res. 2: 911934.Google Scholar
Zamora, R. and Camacho, I. (1984a) Evolución estacional de la comunidad de aves en un encinar de Sierra Nevada. Doñana Acta Vertebr. 11: 2543.Google Scholar
Zamora, R. and Camacho, I. (1984b) Evolución estacional de la comunidad de aves en un robledal de Sierra Nevada. Doñana Acta Vertebr. 11: 129150.Google Scholar
Figure 0

Figure 1. Pied (PiFly) and Spotted (SpFly) Flycatcher density during the period 2004–2006. The highest recorded value was considered for each 10-day period.

Figure 1

Table 1. Comparative abundance of Pied (PiFly) and Spotted (SpFly) Flycatchers in each fortnight during the period 2003–2006 expressed as the number of individuals detected. 2FAug: second fortnight in August: 16–31 August. 1FSep: first fortnight in September: 1–15 September. 2FSep: second fortnight in September: 16–30 September.

Figure 2

Table 2. Insects and fruits in the diet of Pied and Spotted Flycatchers in each fortnight, and foraging techniques, during the period 2002–2006. Insect numbers are feeding attempts on the ground or in flight, and fruit numbers are fruits eaten when the bird was perched or in flight. 2FAug, 1FSep, 2FSep: as in Table 1.

Figure 3

Figure 2. Variation in fruits consumed by Pied and Spotted Flycatchers throughout the morning during 16 August–30 September considering the period 2002–2006 as a whole. Percentages of the total number of fruits consumed by Pied (n = 156) and Spotted (n = 83) Flycatchers.

Figure 4

Table 3. Number of feeding visits by frugivorous birds to fleshy-fruited plants in each fortnight during the period 2002–2006. During each feeding visit the bird ate at least one fruit. SD: seed disperser. SE: seed eater. 2FAug, 1FSep, 2FSep: as in Table 1.

Figure 5

Table 4. Fruit selection by principal frugivorous bird species (S: Jacobs index) during 16 August–30 September considering the period 2002–2006 as a whole. S varies between −1 (maximum negative selection) and 1 (maximum positive selection), with the value 0 if selection does not occur (plant species visited according to availability). See Table 3 for feeding visits by each bird species to each plant species. Availability of plant species with ripe fleshy fruits is expressed as the proportion of the total number (n = 741) of qualitative occurrences of these species in the sampling units. The body weight in grams for each bird species appears in parentheses.