Habitat use

The relative use of the two available habitats (marshy and non-marshy ones) by the LWfG at Kerkini Lake was based on visual observations of the LWfG flock during the wintering periods 2012–2013 and 2013–2014. The size of the flock (number of individuals) and the type of feeding habitat were recorded on 3–4 days weekly during the daytime, throughout the period that LWfG were present in this area, i.e. from early October to middle December in both wintering periods, as well as during February and early March 2014 (BirdLife Norway and WWF Finland 2016).

Food availability

Relative cover (%) of each plant species in the marshy habitat was estimated on nine field samplings (100 0.25 m² square quadrats at each sampling site) when dropping collection was also undertaken (Cook and Stubbendieck Reference Cook and Stubbendieck1986). Sampling was conducted at a regular interval from early October to mid-December in 2012 and 2013, the period when LWfG winter at Kerkini Lake. Availability of each plant species was based on the relative cover of vegetation in its feeding area. This was estimated by excluding mosses, bare soil and those plant species which were not consumed by LWfG at all, mainly Bidens tripartita, Cirsium sp., Conyza canadensis, Euphorbia villosa and Xanthium strumarium (Markkola et al. Reference Markkola, Niemelä and Rytkonen2003).

Dropping collection

Fresh droppings from LWfG were collected at Kerkini Lake during the wintering periods mentioned earlier (Appendix S1 in the online supplementary material). We observed the LWfG flock with a telescope without causing disturbance and we located the exact feeding place of the birds. In the cases when the LWfG flock was not mixed with other goose species, we went in situ and collected only fresh droppings. On all collection dates, the number of droppings used in analysis was less than the number of birds in the flock, in order to minimise the possibility of including different droppings belonging to the same individual. In a few cases, a pile of several droppings was found in the field, in which case only one dropping was analysed to estimate diet composition for the same reason. In total, during the first and the second wintering period in the marshy habitat at Kerkini Lake, 65 and 181 droppings of LWfG were analysed, respectively. Each dropping was preserved separately in a plastic bag.

Dietary composition

Microhistological analysis of droppings is the most frequently used method to estimate the diet composition of wild and tame herbivores (Paola et al. Reference Paola, Cid, Brizuela and Ferri2005). This technique causes minimal disturbance to animals in feeding studies of secretive and endangered species (Holechek and Gross Reference Holechek and Gross1982a), such as the LWfG. It is based on the identification of fragments of epidermal tissue in the faeces of herbivores that are assigned to dietary species by comparison with parts of identified plant species which are available to herbivores (Litvaitis et al. Reference Litvaitis, Titus, Anderson and Bookhout1996). The relative frequency of each species can then be compared with the availability of each species in the field.

The dropping samples were oven-dried at 60^°C for 48 hours, grounded, mixed thoroughly and sieved through a 1-mm mesh screen to ensure particle uniformity. Five microscopic slides were prepared per dropping. Twenty systematic fields per slide were examined for particle frequency, with a field defined as the area visible on a microscope slide at 100 x magnification. The relative frequency of each plant species was calculated as its frequency divided by the sum of frequencies of all species. Relative frequency accurately estimates relative percentage of dry weight composition of diets (Holechek and Gross Reference Holechek and Gross1982b). Only particles containing epidermal tissue were considered. Hairs and trichomes were disregarded, unless they were attached to identifiable epidermal tissue. Each plant species identified in the droppings was assigned to one of the following forage classes: (1) grasses, (2) other graminoid species (Cyperaceae and Juncaceae families), (3) aquatic plants, i.e. submerged, emerged and amphibious species that occur on permanently or seasonally wet environments and (4) forbs (all other broadleaved herbs present in the non-marshy grassland area).

The most common plant species presented in the marshy habitat at Kerkini Lake (about 60 species) were also collected in plastic bags and pots. Special attention was taken to collect several plant parts (stems, flowers, fruits, etc.) when these were available. Microscopic slides containing the epidermal tissue of the plant parts were then prepared for comparative purposes. The same pattern in diet composition of LWfG was observed during 2012–2013 and 2013–2014, as was expected, since LWfG used the same habitat (the marshy habitat near the shoreline) in both wintering periods; therefore data were combined over years.

Differential digestibility of different food items may bias potential estimates of herbivore diets, particularly when shrubs or forbs are a major component of the diet (Gill et al. Reference Gill, Carpenter, Bartmann, Baker and Schoonveld1983, Leslie et al. Reference Leslie, Vavra, Starkey and Slater1983). In grazers however, microhistological analysis of faeces is considered an accurate and precise method to estimate the diet composition (Bartolomé et al. Reference Bartolomé, Franch, Gutman and Seligman1995, Mohammad et al. Reference Mohammad, Pieper, Wallace, Holechek and Murray1995) and the usefulness of calculating correction factors to deal with differential digestibility is questioned (Paola et al. Reference Paola, Cid, Brizuela and Ferri2005). According to Alipayo et al. (Reference Alipayo, Valdez, Holechek and Cardenas1992), the problems of bias can be alleviated to a great extent by the systematic training of the observer(s) using the procedure described by Holechek and Gross (Reference Holechek and Gross1982a,Reference Holechek and Grossb), rather than applying correction factors that compensate for potential differential digestibility of various food items. In this study, it was assumed that results from the microhistological analysis of LWfG droppings are reasonably accurate, because all recommended techniques were incorporated into the analyses.

Diet selection

Selection indices (ŵ_i) for each one of the forage categories in both study areas, as well as for every plant species identified in the LWfG’s droppings (except those species that constitute less than 1% of the diet) at Kerkini Lake, were calculated as: ${\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\frown$}}\over w} _i} = {{{o_i}} \over {{p_i}}}$ , where o_i is the proportion of used resource units and p_i is the proportion of available resource units. The standardised selection index B_i (Krebs Reference Krebs1999) was also calculated according the formula: $Bi = {{{{\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\frown$}}\over w} }_i}} \over {\sum\limits_{i = 1}^n {{{\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\frown$}}\over w} }_i}} }},$ where B_i is the standardized selection index for species i, and ŵ_i is the selection index for species i. Standardized selection indices for all forage resources add up to 1 and in essence give the probability of selection of forage resource i in case of equal availability of all resource categories. We tested the null hypothesis of no selection using the G-test (Krebs Reference Krebs1999): ${\chi ^2} = 2\sum\limits_{i = 1}^n {\left[ {{u_i}\ln \left( {{{{u_i}} \over {U{p_i}}}} \right) + {m_i}\ln \left( {{{{m_i}} \over {{m_i} + {u_i}{M \over {U + M}}}}} \right)} \right]} ,$ where χ² is the Chi-squared value with (n – 1) degrees of freedom, u_i is the number of observations using resource i, m_i is the number of observations of available resource i, U is the total number of observations of use (i.e. $\sum {{u_i}}$ ), M is the total number of observations of availability (i.e. $\sum {{m_i}}$ ) and n is the number of resource categories.

Standard errors of selection indices were calculated using the formula: ${s_{\bar w}}_i = \sqrt {{{\left( {1 - {o_i}} \right)} \over {U{o_i}}} + {{\left( {1 - {p_i}} \right)} \over {{p_i}M}}} ,$ where ${s_{\bar wi}}$ is the standard error for a selection index and the other terms as defined above. 95% confidence intervals (CI) for selection indices were calculated using the Bonferroni correction as: ${\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\frown$}}\over w} _i} \pm {z_{0.0125}}{s_{\bar wi}}$ for the four forage categories, and ${\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\frown$}}\over w} _i} \pm {z_{0.03125}}\;{s_{\bar wi}}$ for the 16 plant species which were identified in the LWfG droppings and their correspondent percentage in the diet composition was equal or above 1%.

Confidence intervals of selection indices that do not include the value 1 indicate significant selection. If confidence intervals overlap with unity then the selection index does not differ from a value for α = 0.05, i.e. there is no selection for or against the forage category. Indices of selection were then estimated based on the ratio of diet composition to the relative availability of food item to the LWfG. Values of indices above and below 1 indicate significant selection for or against a plant species respectively (Krebs Reference Krebs1999).

Food nutrient content

During 2015, based on the diet selection data, we collected representative samples of the four most highly selected plant species (Echinochloa crus-galli, Cyperus esculentus, Scirpus lacustris and Ranunculus sceleratus) and the four forage categories (grasses, other graminoids, aquatic plants and forbs) in the middle of November (i.e. about the mid-point of the traditional time that LWfG stay at Kerkini Lake) and at the end of December (i.e. after their departure from Kerkini Lake, which usually happens in the middle of December), in order to detect any effects of the nutrient content of available foods for the LWfG on the departure time from Kerkini Lake. These samples were collected separately for each plant species and forage category in three representative sites in the marshy area, oven-dried (55^°C for 48 hrs), ground in a Wiley mill (1-mm screen) and used for the determination of nitrogen (AOAC 1990; crude protein (CP) was determined by N x 6.25), neutral detergent fibre (NDF), acid detergent fibre (ADF) and acid detergent lignin (ADL) (Goering and van Soest Reference Goering and van Soest1970, van Soest et al. Reference van Soest, Robertson and Lewis1991).

Differences among vegetation categories and plant species and collection periods in the levels of their chemical composition were determined using analysis of variance. The data on vegetation categories and plant species were analysed separately. Each analysis consisted of four forage types (either four vegetation categories or four plant species) and two periods. The three sites where forage samples were collected were a random factor while forage types and periods were the main fixed effects. When F-tests indicated significant differences, means were compared using LSD (P ≤ 0.05).