Invertebrate sampling

Invertebrates were sampled in 2011 and 2012 to compare prey taxon richness between field margins, crops, grassland and verges (strips of grassy vegetation along roads and ditches) using a modified leaf vacuum (McCulloch MAC GBV 345) with a 12 cm diameter suction tube. Sampled crops were winter wheat (intensively managed), lucerne (cut two or three times per year followed by manure application, no pesticide use) and grassland (high-input silage fields cut five times per year). Each suction sample consisted of five subsamples of 15-seconds vacuum sessions within a bottomless circular frame (50 cm diameter), thus sampling a total area of 0.982 m² per sample. Five field margins were sampled in both years. Two verges were sampled in 2011 and four in 2012. Of each crop type (grassland, lucerne and wheat) two fields were sampled in 2011 and five in 2012. Each margin, verge and field was sampled five times throughout the breeding season, from mid-May through mid-July. Sampling was conducted in sunny and dry weather conditions only. Invertebrate numbers were converted to dry biomass by applying the length-biomass relationships given in Hawkins et al. (1997, Stylommatophora), Ganihar (1997, Isopoda) and Sage (1982, all other taxa).

Figure 1.

Field margin with grasses, forbs and cereals in the first year after sowing. Ganzedijk, The Netherlands, July 2010.

Diet

Skylark nests were located as part of a study monitoring reproductive success and the effect of field margins on breeding and foraging. Foraging habitat use by parental birds was recorded during two one-hour observations on two separate days, observed from a hide using binoculars (see Kuiper et al. 2013 for detailed methods). 95 faecal droppings were collected from 50 broods in 2011 and 16 broods in 2012, with nestlings aged between 5 and 8 days. Samples were collected between 26 April and 6 August, with 70% of the samples being collected in June and July. Nestlings usually defecated when they were handled for weighing and ringing, after which faecal samples were stored in vials with sodium chloride for preservation. Mostly two but sometimes one or three faecal droppings were collected per brood. Samples from nine adult birds were collected when they were caught in mist nets that were placed over the nest for the purpose of placing radio tags for a different study (Ottens et al. 2013).

For examination, the faeces were soaked in water for 30 min and analysed under a binocular microscope at 20× magnification using a standard method (Ralph et al. 1985, Flinks & Pfeifer 1987). Prey fragments were identified to class, order and where possible to family, genus or species level. Field guides, taxonomic keys and reference material were used to aid identification. Because of uncertainties in taxonomy or identification, the subclass Acarina and clade Stylommatophora were used as taxonomic entities equivalent to order, and the superfamily Aphidoidea and suborders Heteroptera and Auchenorrhyncha were used as equivalents to family. Based on the animal remains, the minimum number of individuals per taxon was assessed. Invertebrate length was estimated using a reference collection and information from the literature (Calver & Wooller 1982, Ralph et al. 1985, Flinks & Pfeifer 1987). Diet diversity was calculated as the total number of unique invertebrate taxa present per dropping. The number of prey taxa was used as a measure of diversity rather than a diversity index that incorporates evenness, because studies on this subject indicate that equal amounts of each prey taxon are not necessary to balance nutrient intake (Westoby 1978, Tinbergen 1981, Simpson et al. 2004).

The method of faecal analysis to study the diet of birds causes less disturbance than invasive methods such as neck-collars and allows for a better determination of food items than observation by telescope or camera. Concerns have been raised about the differential digestion of prey items, which could yield inexact estimations of the proportions of different prey groups (Moreby & Stoate 2000), but in a comparative study with Skylark nestlings, no differences in diet composition were detected between faecal analysis and applying neck collars, possibly because the passage of food through the gut is relatively quick in Skylark nestlings (Poulsen 1995).

Data analyses

Differences in invertebrate diversity between habitat types were analysed using a Generalised Linear Mixed Model with unstructured covariance structure. The number of taxa identified after suction sampling was entered as the dependent variable with Poisson distribution and identity link (taxa included Araneae, Auchenorrhyncha, Chilopoda, Coleoptera, Diplopoda, Diptera, Heteroptera, Hymenoptera, Isopoda, Lepidoptera imagoes, Lepidoptera and Symphyta larvae, Opiliones, Orthoptera and Stylommatophora). Sampling site was entered as subject and catch round as the repeated factor, so that each catch round in the same margin or field was considered a repeated observation. Habitat type and catch round were added to the model as fixed factors and the interaction between habitat type and catch round was entered to detect whether differences in prey diversity changed over time. To account for possible differences between years, year was added as a random factor. When differences were significant, pairwise post-hoc tests were conducted with Bonferroni-correction.

To characterise the diet in more detail, the length of consumed invertebrate prey items was compared between nestlings and adults using a General Linear Mixed Model. The length of the prey items was logtransformed to achieve normality of residuals and entered as the dependent variable. Nest and adult bird identity were entered as random factor, so that each prey item eaten by the same brood or adult bird was regarded as a repeated observation. The life stage of the subjects (nestling or adult) was entered as an explanatory factor. Year was added as a factor to control for possible differences in prey size between years.

To assess the effect of foraging in field margins on the diversity of the nestling diet, Generalised Linear Mixed Models were used. The number of invertebrate orders or families in the diet per dropping was entered as the dependent variable with Poisson distribution and identity link. Nest identity was entered as the subject and dropping as the repeated factor, so that each dropping collected from the same brood was considered a repeated observation. The use of field margins as a foraging habitat by parents during the foraging observations was entered as a factor. To test for possible changes in diet diversity over the course of the breeding season, sampling date was added as a covariate. Sampling date was also tested in a quadratic relationship with diet diversity, but this did not provide a better fit to the data and only the linear term was used in the final models. Year was added as a random factor to control for possible differences in prey diversity between years. Only nests where foraging observations had been conducted were included in this analysis (53 nests, of which 20 had been fed from field margins). Chi-square tests of independence were used to test whether the frequency of occurrence of invertebrate orders and families in the diet differed between nestlings fed from field margins and those not fed from field margins. The Benjamini-Hochberg correction was applied to reduce the chance of false positives when performing multiple tests (Benjamini & Hochberg 1995, Waite & Campbell 2006).

All statistical analyses were performed with SPSS v.21 (IBM, Armonk, New York). Means are given with standard errors.

Available prey

Summed over all habitat types, Diptera (true flies), Coleoptera (beetles) and Araneae (spiders) were the most abundant prey groups sampled by suction sampling (Figure 2). Also Isopoda (woodlice), Stylommatophora (snails and slugs), Auchenorrhyncha (cicadas) and Heteroptera (bugs) were relatively common. Opiliones (harvestmen), Lepidoptera (moths and butterflies), Hymenoptera (ants and sawflies) and Orthoptera (grasshoppers and crickets) were found in small quantities.

The taxon richness of invertebrate prey differed significantly between the sampled habitat types (F_4,32 = 25.7, P<0.001) and between the five catch rounds (F_4,32 = 9.3, P<0.001). In addition, the differences in invertebrate diversity between habitat types changed over time (interaction between habitat type and catch round: F_16,32 = 1.9, P<0.05). Field margins contained more invertebrate taxa than winter wheat throughout the entire sampling period, more than grassland during both catch rounds in June, and more than lucerne in the end of June. There were no differences between field margins and road verges. Averaged over the whole sampling period, the mean number of taxa was 5.4 ± 0.3 in field margins, 6.0 ± 0.4 in road verges, 3.9 ± 0.3 in lucerne, 2.9 ± 0.3 in grassland and 2.1 ± 0.2 in winter wheat.

Figure 2.

Biomass contributions of invertebrate groups in five different habitat types, averaged over the breeding seasons of 2011 and 2012 (+SE). Note the variable scale of the y-axes. Larvae I include Lepidoptera and Symphyta larvae, Larvae II include Diptera and Coleoptera larvae.

All invertebrate taxa, with the exception of Diptera and larvae of Diptera and Coleoptera, were found in higher quantities in field margins and verges than in grassland, lucerne and winter wheat (Figure 2). Certain taxa were found almost exclusively in field margins and verges, such as Isopoda, Orthoptera, Hymenoptera, Stylommatophora, Heteroptera, Auchenorrhyncha and Opiliones.

Diet composition

In the diet of 66 broods, 1619 invertebrate prey items were recognised, of which 1611 could be identified to at least order level (see Table A1 for a detailed overview). In the faeces of nine adult birds, remains of 68 prey items were found that could all be identified to at least order level (Table A2). Some prey orders, including Stylommatophora, Isopoda and Lepidoptera, could never be identified to family level and are thus underrepresented in analyses of family diversity.

Coleoptera were the most important prey group for nestlings as well as adult birds. 94% of all broods and 100% of all adults had eaten Coleoptera (Figure 3) and this group accounted for 44% and 53% of the total number of invertebrate prey items eaten by nestlings and adults, respectively (Figure 4). Eleven families of Coleoptera were identified in the diet of nestlings, of which Carabidae (62%), Elateridae (14%), Curculionidae (7%) and Byrrhidae (6%) were the most numerous (Table A1). One quarter of the Coleoptera eaten by nestlings were larvae, while adults ate imagoes only (Figure 4).

Figure 3.

Frequency of occurrence of different invertebrate and plant groups in the diet of 66 Skylark broods and nine adults (+SE).

Figure 4.

Proportion of invertebrate prey groups in the diet of Skylark nestlings and adults, based on prey numbers.

Lepidoptera, Diptera, Hymenoptera and Araneae each formed between 7–15% of the diet of nestlings and occurred in the diet of 70–86% of all broods. Adults ate fewer Lepidoptera than nestlings and only took imagoes, while nestlings received a large proportion of larvae (64%). Of the Diptera that could be identified, Tipulidae were the most abundant family (95%). Within the Hymenoptera, the Symphyta were by far the most frequently eaten family (90%), mainly pupae (60%) and larvae (33%). Within the Araneae, the families Lycosidae (75%), Linyphiidae (13%) and Salticidae (10%) were the most numerous. Minor prey groups for nestlings were Stylommatophora, Hemiptera, Opiliones, Orthoptera and Isopoda, which were eaten by 17–32% of all broods but comprised only 1–2% of the total number of prey items. Oligochaeta, Diplopoda, Neuroptera and Acarina occurred in the nestling diet sporadically. The last six groups were not found in the diet of adults.

Figure 5.

Mean number of invertebrate orders and families in the diet of Skylark nestlings of which the parents did or did not forage in field margins (+SE).

Nestlings ate significantly larger invertebrates than adults (F_1,1673 = 42.9, P<0.001). The size of nestling prey ranged between 0.3 and 50 mm, with a mean of 10.7 ± 0.2 mm. The mean prey size of adult birds was 6.1 ± 0.5 mm, ranging between 1 and 16 mm. There were no differences in prey sizes between years (F_1,1673 = 2.6, P = 0.10).

Both nestlings and adults consumed plant material (Figure 3), the vast majority being seeds and occasionally stems, leaves and inflorescences of Triticum and Secale (Tables A2, A3). Adult birds also ate other Poaceae, such as Setaria and Poa annua. Nestlings were fed a range of Dicotyledonae, including seeds of Taraxacum officinale (Asteraceae), Capsella bursa-pastoris (Brassicaceae) and Lamium amplexicaule (Lamiaceae). Remains of Euphorbiaceae, Caryophyllaceae, Geraniaceae, Plantaginaceae, Polygonaceae and Violaceae were also found in the diet. Adults ate seeds of Asteraceae and Polygonaceae and leaves from unidentified Dicotyledonae. Both nestlings (47%) and adults (44%) had small stones (mean length 1.3 ± 0.11 mm, predominantly gastroliths) and sand in their faeces. Two nestlings had eaten pieces of charcoal.

Diet diversity and effect of field margins

The mean number of invertebrate orders and families in the diet was significantly larger for nestlings that were fed from field margins than for other nestlings (orders: F_1,78 = 6.6, P<0.05; families: F_1,78 = 8.8, P<0.01; Figure 5). The diversity of invertebrate families in the diet decreased significantly over the course of the breeding season (F_1,78 = 9.1, P<0.01), while the diversity of invertebrate orders remained stable (F_1,78 = 0.2, P = 0.7).

When comparing the frequency of occurrence of invertebrate taxa in the diet (Figures 6, 7), the diet of broods that received food from field margins contained higher frequencies of the order Opiliones (χ²₁ = 4.2, P = 0.042), the Dipteran family Tipulidae (χ²₁ = 8.3, P = 0.004) and the Coleopteran families Elateridae (χ²₁ = 6.3, P = 0.012), Byrrhidae (χ²₁ = 6.1, P = 0.013) and Curculionidae (χ²₁ = 4.1, P = 0.044), but the differences did not remain significant after applying the Benjamini-Hochberg correction for multiple testing.

Figure 6.

Frequency of occurrence of different invertebrate orders in the diet of Skylark nestlings of which the parents did or did not forage in field margins (+SE).

Figure 7.

Frequency of occurrence of different invertebrate families in the diet of Skylark nestlings of which the parents did or did not forage in field margins (+SE).