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Moving polewards in winter: a recent change in the migratory strategy of a pelagic seabird?

Abstract

Background

During the non-breeding period, many birds migrate to milder areas, found closer to the equator than their breeding sites. Opposite movements are very rare. In the Southern Ocean, the abundance of 13C declines markedly with more southern latitude, providing a characteristic 13C isoscape. This can be used as a tracer for the movement of seabirds between breeding and inter-breeding areas, by comparing stable isotope ratios of feathers grown at different times of the year.

Results

We studied seasonal movements of Thin-billed prions (Aves, Procellariiformes), breeding at the Subantarctic Falkland/Malvinas Islands, compared with those of Wilson's storm-petrels breeding in the Antarctic South Shetland Islands. The two species showed opposite migratory movements. While Wilson's storm-petrels moved to warmer waters north of the Drake Passage in winter, Thin-billed prions showed a reversed movement towards more polar waters. Carbon stable isotope ratios in recent and historical feathers indicated that poleward winter movements of Thin-billed prions were less common historically (45% in 1913-1915), and have only recently become dominant (92% in 2003-2005), apparently in response to warming sea temperatures.

Conclusions

This study shows that pelagic seabirds can rapidly change migration strategies within populations, including migration towards more poleward waters in winter.

Background

Migration is thought to be an adaptive strategy, when resources found in the breeding area during the breeding season become scarce during the non-breeding season or climate becomes unfavourable. Animals can then displace to more productive or milder areas [1]. The places animals select for the winter season are usually warmer, e.g. transequatorial to winter in the opposing hemisphere's summer, or further towards the equator within the same hemisphere (latitudinal migration) or lower in the mountains (altitudinal migration). Opposite movements are very rare, and virtually absent in terrestrial birds [1].

Many seabirds are too small to carry devices presently available for satellite or GPS tracking. Small pelagic seabirds are difficult to observe in their vast marine ecosystems, and little is known about their distribution and behaviour outside the breeding season. Stable isotopes provide a powerful tool to study movements and trophic position of such birds if tissue grown at different times during the year can be matched to an isotopic gradient across the area of movement [2].

Since keratin is a highly stable molecule, the nitrogen and carbon isotopic composition of feathers remains unchanged after the completion of growth. Thus, historical feathers provide a window that allows us to look back in time, and stable isotope analysis can therefore be applied to study changes in migratory patterns due to environmental change. Historical feathers from museum specimens have been analysed for stable isotopes in few seabird species, chiefly to investigate reasons for population change. Declining δ15N levels, indicative of declining trophic levels, were found in Northern Fulmars Fulmarus glacialis[3], and Marbled Murrelets [4, 5]. Declining carbon isotope ratios were found in Rockhopper penguins Eudyptes chrysocome, and were interpreted as a decline in primary productivity and thus, the carrying capacity, of the ecosystem [6, 7]. The aim of the present study is to use stable isotopes to understand the movements of a small pelagic seabird, both from recent and historical samples.

Previous studies suggested that the carbon stable isotope ratio δ13C in the Southern Ocean declines between 40 and 80°S [8–11]. By compiling data from the literature and modeling this trend, we here aim to verify if seasonal latitudinal movements of seabirds in the Southern Ocean will result in different δ13C values of adult feathers grown during winter, and chick feathers and induced adult feathers grown during the summer. The latter both represent the breeding season equally well and do not differ in their stable isotope ratios (see Methods).

We then applied the results of the spatial model to interpret data on seabird movements. Our focal species in this study was an abundant pelagic seabird in the Southern Ocean, the Thin-billed prion Pachyptila belcheri, sampled at a breeding site at New Island Nature Reserve in the Falkland/Malvinas Islands, at 52°S (Fig. 1B). Thin-billed prions breed on Sub-Antarctic islands. Their year-round distribution is poorly known. They are highly pelagic and mobile, scatter widely and are not attracted by ships, making their observation in Southern Ocean winter waters difficult. Based on stable isotopes of adult feathers grown during winter, it has been suggested recently that Thin-billed prions move towards more polar waters for the winter, both from their breeding populations from Kerguelen [12, 13] and the Falkland Islands [10].

Figure 1
figure 1

Carbon stable isotope ratios and breeding sites. A. Carbon stable isotope ratios in Southern Ocean plankton and predators (fish and squid), The sample size refer to discrete species × location data points. An interpolated isoscape was derived from phytoplankton data. Data points are from a review of available literature. B. Breeding sites of the two study species (KG = King George Island, South Shetlands, FI = New Island, Falkland Islands/Malvinas), distribution of isotope values from the interpolated isoscape in the study ares, and pictures of corresponding chicks. C. Stable isotope ratios of feathers representing diet during the breeding season (chick feathers and induced adult feathers) and naturally moulted adult feathers (representing the interbreeding season), showing opposite movement of Thin-billed prions and Wilson's storm-petrels during migration

We included samples of Wilson's storm-petrels Oceanites oceanicus from a breeding site at the South Shetland Islands at 62°S (Fig. 1B), as a reference for the location (δ13C) and relative trophic level (δ15N). Wilson's storm-petrels feed in Antarctic waters during the chick-rearing period, and are known to migrate north in winter [9, 14].

To compare historical and recent migration patterns, we obtained feather samples of Thin-billed prions from skin collections, including only birds collected during the breeding season in the Falkland Islands or adjacent waters. The period 1913 - 1915, ninety years before the present study, was particularly well represented in museums. We compared the historical and recent samples after correcting for long-term-changes in δ13C due to the Suess effect (see methods below).

In summary, the aim of the present analysis was to model the δ13C distribution in the Southern Ocean as baseline for migration studies and to compare the migration pattern of Thin-billed prions in recent and historic times.

Results

Southern ocean isoscape

We compiled data from the literature to model the δ 13C distribution (Fig. 1A). Because 13C was more enriched in higher trophic levels (Fig. 1A), we only used stable isotope ratios of pelagic primary producers to calculate a δ13C isoscape. The Southern Ocean in general, and the Southwest Atlantic in particular, exhibit a strong gradient in carbon stable isotope baseline values (Fig. 1A and 1B, see Fig. S1 in Supplementary material for additional details). This steep gradient ceases abruptly and completely at around 40-45°S, the location (variable in latitudinal position around the globe) of the northern boundary of the Southern Ocean, defined through the Southern Subtropical Front.

Recent feathers - comparison between two species

Feathers grown during the breeding season reflected the more northerly breeding site of Thin-billed prions at the Falkland Islands, compared to Wilson's storm-petrels, breeding south of the Drake Passage (Fig. 1B,C). δ13C varied with species and time of the year, while the largest variation in the data was explained by the interaction between species and time (Table 1). The data thus confirm opposite migration movements: Most Thin-billed prions spent the summer north of the Polar Front, i.e. the northern limit of the Drake Passage, and the winter south, while Wilson's storm-petrels showed the opposite distribution (Fig. 1C). The δ13C values for Thin-billed prions in winter were very similar to those of Wilson's storm-petrels in summer (-23.7 ± 0.2‰ vs. -24.9 ± 0.1‰) and vice versa (-19.2 ± 0.1‰ for both Thin-billed prions in summer and Wilson's storm-petrels in winter). Some individuals of both species differed strikingly from the most common isotopic values, demonstrating some intra-specific flexibility in winter distribution.

Table 1 Differences between species and times of the year in stable isotope ratios.

The δ15N signatures show that Wilson's storm-petrels maintained a relatively higher trophic level over the year (Fig. 1C). δ15N was best explained by species differences (P < 0.001, η2 = 0.581), followed by location (represented by δ13C values: P < 0.001, η2 = 0.387), while time and time*species interactions were of minor importance (Table 1).

Comparison with historical feathers

Historical and recent feathers of Thin-billed prions were isotopically distinct (Fig. 2A, Wilk's λ = 0.65, P < 0.001). This was due to 3.3‰ lower carbon isotope ratios in recent compared with historical feathers (-23.7 ± 0.2‰ vs. -20.4 ± 0.3‰). Thus, more Thin-billed prions (92%) moult in Antarctic waters now than historically (45%), using a cut-off point of -21‰ (see Fig. 2A). This was based on a frequency distribution of observed δ13C values, which had a bimodal distribution, with a minimum at -21 ‰ (Fig. 2A). The nitrogen stable isotope ratio remained constant over time (Table 2: P = 0.51, see also Fig. 2B for similar regression lines).

Table 2 Comparison of nitrogen stable isotope ratios of Thin-billed prions breeding in the Falkland Islands.
Figure 2
figure 2

Differences in carbon stable isotope ratios of feathers of adult Thin-billed prions. Recent samples (N = 62) were collected at New Island, and historical samples (N = 62) are from museum specimens. Histogram categories in 2A had a width of 2‰, with labels showing the midpoint. In 2B, recent and historic samples of Wilson's storm-petrels were included for comparison.

We analysed samples from eight Thin-billed prions collected at Rinconada beach in Chile in the summers 1968 and 1969, 21 birds from Argentinean beaches, collected between 1974 and 1984 and four birds collected at beaches in Brazil in 1997 and 2002 (Fig. 3). All except one bird had carbon isotope ratios indicating northern moulting areas.

Figure 3
figure 3

Stable isotope ratios of Thin-billed prions from wrecks. Carbon stable isotope ratios of birds found dead on beaches in winter, compared to birds sampled in the Falklands Islands in the breeding season. The dotted trendline was calculated from the breeding season birds only, but the clustered data distribution did not allow us a regression analysis. In 3B, recent and historic samples of Wilson's storm-petrels were included for comparison.

In Wilson's storm-petrels, historical and recent feathers were also isotopically distinct (Fig. 2A, Wilk's λ = 0.93, P = 0.043), but the high Wilk's λ (close to 1) and P-value (close to 0.05) indicated that the group means are by far less different than those observed in Thin-billed prions (Fig 2B). Comparatively small differences (1.0‰) were observed in mean carbon isotope ratios in recent compared with historical feathers of Wilson's storm-petrels (-19.2 ± 0.1‰ vs. -18.2 ± 0.2‰; t = 2.5, d.f. 85, P = 0.015), while nitrogen stable isotope ratios did not differ (t = 0.9, d.f. 85, P = 0.368).

Discussion

In the present study, we found that two small pelagic seabirds had contrasting migratory patterns, and that the recent distribution of moulting Thin-billed prions with predominantly poleward winter migration differed from that observed historically. The trophic level of Thin-billed prions, in contrast, remained constant over time, suggesting that prions responded to changes in their environment by moving to a different location, while any possible changes in diet would be limited to dietary sources of similar trophic level. Wilson's storm-petrel feathers showed a much smaller change in carbon isotope ratios (Fig. 2B and 3B), indicating that baseline level changes alone would not explain the observed differences in Thin-billed prions. In addition, the shift in isotope ratio in Thin-billed prions is really large, almost certainly too large to be caused by changing primary productivity.

Consistency in trophic level is also seen in the comparison between the species, where Wilson's storm-petrels maintained a relatively higher trophic level over the year (Table 1), and in historical feathers (Fig. 2B). This is consistent with observations from regurgitated food during the breeding season. Wilson's storm-petrels commonly took Antarctic krill Euphausia superba and lanternfish Electrona antarctica of 15-50 mm during summer [15], while Thin-billed prions fed predominantly on small crustaceans of 2-20 mm, mainly amphipods Themisto gaudichaudii, copepods Calanus spec., krill Euphausia lucens and lobster krill Munida gregaria[10, 16]. Thus, Thin-billed prions, although nearly four times heavier than Wilson's storm-petrels, consistently took smaller prey and fed at a lower trophic level than the storm-petrels, as reflected in lower δ15N signatures (Fig. 1C).

The observed differences in the migratory strategies between the species can most likely be explained by differences in the body size and in the abundance and distribution of their preferred prey. Wilson's storm-petrels are the smallest Antarctic endotherms at 38 g, and low winter temperatures might constrain their distribution. In winter, they scatter widely but are often observed over the Patagonian Shelf. Lanternfish (myctophiids) are the most abundant small pelagic fish in the area, with larvae occurring throughout the year [17]. As lanternfish are one of the preferred prey of Wilson's storm-petrels [15], the shelf-break zone offers good feeding opportunities for them in winter. Additionally, Wilson's storm-petrels attend feeding flocks following fisheries vessels to pick up small pieces of discards and may benefit from increased human activity [18].

In contrast, Thin-billed prions do not attend vessels. They depend on lower trophic level prey, especially amphipods Themisto gaudichaudii[10, 16], which occur throughout the Southern Ocean including the Patagonian shelf [19], mainly feeding on copepods. The ecosystem of the Patagonian shelf is strongly influenced by temperature. Massive blooms of gelatinous zooplankton occurred when the water temperature rose by 2°C, rendering the tidal fronts off Patagonia less prominent and depressing copepod populations [20]. Rising sea temperatures might therefore cause significant bottom-up effects in the food chain.

Could such effects have caused the shift in the frequency of migration routes of Thin-billed prions? High rates of genetic change in preferred migratory direction have been observed in blackcaps Sylvia atricapilla as a consequence of assortative mating [21], indicating that the evolution of new migratory preferences can be remarkably rapid in birds. It is not known to which degree the direction of migration is genetically determined in seabirds. A recent study on the faithfulness of individual Thin-billed Prions to a moulting area within and among years suggested a flexible migratory strategy [22]. Feathers of marked Thin-billed Prions were sampled over several seasons. Although individuals moulting in an area in one year were more likely to do so again in the subsequent year, several birds changed between Antarctic and South American moulting areas or vice versa [22].

Hence, both genetic and phenotypic mechanisms could cause a change in migratory direction if birds that migrated (and moulted) north suffered a higher mortality than birds migrating to the Antarctic. There is, in fact, evidence that Thin-billed prions were affected by several large-scale mortality events, with major wrecks in New Zealand in 1974 and 1986 [23], in South Africa in 1984 [24] and in Brazil in 1954, 1982, 1984 and 1996 [25]. During the 1996 event in Brazil alone over 10,000 individuals were beached, and unknown numbers of birds died at sea. These major wrecks all occurred in the middle of winter (July-August), beached birds were underweight, without large fat deposits and with empty stomachs and many birds that were found dying soon recovered once receiving adequate food. These observations suggest that winter mortality can be high over the Patagonian Shelf and other northern moulting areas, and that the most likely cause of these events are food scarcities in mid winter. Abnormal weather conditions were not regularly observed during these events, and were interpreted as proximal cause of strandings of birds in already poor condition [25]. The present data suggest that winter mortality might have hit preferentially northern moulting birds (Fig. 3), although data on mortality in the south are lacking.

Given their large populations there are surprisingly few sightings of Thin-billed prions in the Antarctic, and their winter distribution has mainly been inferred from beached recoveries. This may be partly due to the absence of observers in the vast open ocean area, and due to the fact that Thin-billed prions are not concentrated at the ice edge as some other, more readily observed species [26].

Thin-billed prions are not the only seabird migrating polewards for the winter. Blue petrels Halobaena caerulea are a closely related species, which replace Thin-billed prions in some parts of their circumpolar range, such as South Georgia. They have very similar stable isotope signatures [[27], adult Blue petrel feathers from South Georgia: δ13C = -24.1 ± 0.9 and δ15N = 7.9 ± 0.5], indicating similar latitude and trophic level during moult. In fact, they are often observed in feeding flocks together with prions [28].

Conclusions

In conclusion, the present data strongly suggest a change of migration patterns in a small pelagic seabird. There are fundamental differences from the migration of land birds with their major flyways and overwhelmingly equator ward direction. In the polar oceans, the primary productivity is restructured in winter, and can be very high in near-surface waters, thus generating migration towards the polar areas. Our data from Thin-billed prions further support this view, and indicate that seabird migration patterns may quickly respond to changes such as those caused by global warming.

Methods

The fieldwork was carried out in the framework of long-term studies and under licence (Falkland Islands Government Environmental Planning Department, Umweltbundesamt Germany).

The Southern Ocean carbon isoscape

Authors sampling in different areas of the Southern Ocean noted a southward decline in δ13C of phytoplankton and subsequently, higher, trophic level organisms [9, 10]. Across the Drake Passage, the area relevant to the present study, a 7‰ gradient in the δ13C of suspended particulate organic matter (POM) has been observed, from -23.2 ‰ at 53°S to values as low as -30.3 ‰ at 62°S [11].

The southward decline in δ13C does not track the abrupt changes in water chemistry and plankton species composition associated with the Polar Front Zone, but show a rather gradual change with latitude [11, 29]. Studies did not report any significant changes in phytoplankton carbon or nitrogen concentrations or C/N ratios with latitude (e.g. Drake Passage: [11]], which would be indicative of differences in plankton standing crop or biochemistry (e.g., lipid content). The latitudinal change in δ13C was, however, highly correlated with sea surface temperatures and with the calculated concentration of CO2(aq) at equilibrium with atmospheric CO2[11, 29], suggesting that CO2(aq) significantly influences δ13C in ocean surface waters, and throughout the food chain.

For latitudinal trends and comparison of trophic levels (Fig. 1A), we compiled data published in the Southern Ocean for δ13C of phytoplankton and POM [29–41], planktonic crustaceans [10, 12, 33, 36–40, 42–48] and pelagic fish and squid [10, 12, 32, 37, 38, 40, 42, 44, 48–52]. Gerhard Fischer, University of Bremen, kindly provided an unpublished dataset from Fig. 1 of [34]. We used ArcView 9.3 (ESRI), to plot the distribution of 326 sampling locations for phytoplankton and POM from 30°S southwards (Fig. 4), and we used a nearest-neighbor interpolation in the Spatial Analyst tool to model and visualize the latitudinal trend in δ13C (Fig. S1, see also Fig. 1A,B).

Figure 4
figure 4

The calculated isoscape after interpolation. Sample locations are marked with crosses. All data were included as given in the original papers, for further details, please see the methods section.

Study site, study species and feather samples

Samples of Thin-billed prions were collected as part of an ongoing study at New Island Nature Reserve, Falkland Islands (51°43'S, 61°17'W) during three consecutive breeding seasons (2003/04, 2004/05, 2005/06). We collected samples representing birds outside the breeding season (adult rectrices and undertail coverts), as well as the breeding season (chick undertail coverts), by gentle pulling and placed them in individual plastic bags. The first tail feathers of chicks including the tail coverts start to emerge after 3 weeks of age [[16], p. 427: 'at 22 d the sheaths of the rectrices can be felt protruding']; therefore, the distal parts of these feathers represent the middle of the nestling growth period of 50 d (i.e. about 25 d).

Wilson's storm-petrels have a circumpolar breeding distribution in the Antarctic. This species is described as a transequatorial migrant [28], although winter records in the southern hemisphere are also common, for example off Brazil in the Atlantic [18] or off Peru in the Pacific [28]. This northerly migration movement of Wilson's storm-petrels was well reflected by the stable isotope signatures of adult and chick feathers sampled at King George Island, South Shetlands [9, 14], and stable isotopes helped to establish that these birds move further south, towards the sea ice edge, to feed up for egg production [9] and that their wintering areas differ between years, depending on the location of rich frontal systems [14]. Wilson's storm-petrels moult their feathers in the winter quarters, and thus, at a similar time to Thin-billed prions (see below).

Sample collection took place in the Tres Hermanos (Three Brothers Hill) colony on King George Island (62°14'S, 58°40'W), South Shetland Islands in the maritime Antarctic from December 1995 to April 2000. About 2000 pairs breed in this colony [53], and we have previously described their general breeding biology [summarized in [54]], diet [15] and provisioning patterns [[55] and references therein]. In 1995-1996, we collected 27 induced feathers of adult Wilson's storm-petrels as part of a ptilochronology study. The outermost right rectrix was pulled during a first control in February 1996 and induced feathers were collected at the time of recapture, in late March 1996. The time of feather growth was thus in the chick-rearing period, simultaneously with growing chick feathers.

Comparison of stable isotope ratios in chick feathers and simultaneously grown induced adult feathers

The findings of a previous analysis indicated that adult and chick feathers undergo a similar isotopic enrichment compared to blood within and between species of Procellariiformes [56]. We compared 27 adult and 11 chick feathers of Wilson's storm-petrels grown simultaneously during the breeding season (Fig. 1C). They were not isotopically distinct (Wilk's λ = 0.96, P = 0.493). As wing, tail and body feathers are grown in the second part of the long nestling periods of petrel chicks, the tissue has already undergone a nearly complete tissue turnover since hatching. Although isotopic enrichment compared to diet was not determined specifically, similar isotope values in chicks and adults suggest that in these species, chick feathers reliably reflect the diet during the breeding season.

Historical feathers

We included 115 feather samples from museum specimens of Thin-billed prions as listed below, including 82 samples from birds collected in the Falkland Islands and adjacent waters in the breeding season, and 33 samples of birds collected dead on beaches in Chile, Argentina and Brazil. We further included 14 historical feathers from Wilson's storm-petrels collected in the South Shetland Islands. Preferably, undertail feathers were taken, or flank feathers if sampling undertail feathers was not permitted. Sequentially moulted primaries indicated that most adults maintained highly conserved isotope values over the entire wing moulting period [22], and previous analyses had shown that undertail feathers, rectrices and flank feathers did not show significantly different stable isotope values. Because in Thin-billed prions, all moult occurs outside of the breeding season [16], and chicks of Thin-billed prions do not fledge until March, we are confident that flank feathers, rectrices and undertail feathers all represent the late autumn and early winter period (April-July). Tail feathers are moulted towards the end of the wing moulting period, which takes 2-4 months in prion species [57], and thus, tail feathers are moulted in early winter in Thin-billed prions.

We obtained samples of Thin-billed prions of the following museums specimens: American Museum of Natural History New York, USA: #445528-445541, 445544-445549, 445552-445564, 445566-445577, 445579-445594, 792675, 792883-792887, Natural History Museum, Tring, UK: # 1925.9.14.1, 1925.9.14.2, 1940.12.6.76, 1932.7.2.16, 1932.7.2.17, 1932.7.2.19-1932.7.2.23, 1949.52.10, 1951.51.2, 1969.2.2, 1969.2.2, 1972.14.1, Museo Argentino de Ciencias Naturales Bernardino Rivadavia, Buenos Aires, Argentina: #42973, 42974, 52110, 52111, 52331, 52372, 52406, 52414, 52770-52774, Naturhistorisches Museum Wien, Austria: NMW 80.541 - 80.550, NMW 87.177, Biozentrum Grindel und Zool. Museum Hamburg, Germany: # 75.106, 75.107, 75.133, Cornell University Museum of Vertebrates, USA: # 25006, 25007, National Museum of Natural History Leiden, Netherlands: # 3269, Museo de La Plata, Argentina: #13326, Museu de Ciências e Tecnologia - PUCRS, Porto Alegre, Brazil: # MCP0705, MCP1116, MCP1120, MCP1395.

We obtained samples of Wilson's storm-petrels of the following museums specimens: American Museum of Natural History New York, USA: # 196198, 196199, 196202, 349447, Natural History Museum, Tring, UK: # 1924.5.8.28, 1924.5.8.29, 1925.10.4.26, 1933.10.16.1, 1933.10.16.2, 1940.12.7.48, 1963.41.2-5.

Sample preparation and stable isotope analysis

Carbon and nitrogen isotope analyses were carried out on 0.65-0.7 mg aliquots, weighed into tin cups. A single feather per sample was cut into small fragments using stainless steel scissors. Studies have shown that mean δ13C values did not shift when feathers were cleaned, supporting the notion that carbon stable isotope ratios are quite robust to minor contamination [58, 59], and this is unlikely to be of any relevance given that differences observed in the present study between birds moulting in Antarctic and more northern areas were very large (-19 vs. -25‰). As cleaning agents may remove contaminants but may also change feather isotope values, either by leaving a residue with a different enough stable isotope ratio to change the measured value or by causing atom exchange [e.g. [59]], we decided not to apply a cleaning protocol. We thus selected feathers free from any obvious contamination, both in recent and historical feathers.

Carbon and nitrogen isotope ratios were measured simultaneously by continuous-flow isotope ratio mass spectrometry (CF-IRMS) using a Costech Elemental Analyser (EA) linked to a Thermo Finnigan Delta Plus XP Mass Spectrometer. Two laboratory standards were analysed for every 10 unknown samples, allowing any instrument drift over a typical 14 hour run to be corrected. Stable isotope ratios were expressed in δ notation as parts per thousand (‰) deviation from the international standards V-Pee dee belemnite (carbon) and AIR (nitrogen), according to the following equation δ X = [(R sample/R standard) - 1] × 1000 where X is 15N or 13C and R is the corresponding ratio 15N/14N or 13C/12C. Based on internal standards (tryptophan), the analytical precision (± 1 SD) was estimated as ± 0.18‰ and ± 0.17‰ for δ15N and δ13C, respectively.

Data analysis

Data analysis was carried out using SPSS 11.0. The isotopic ratios of storm-petrel feathers grown simultaneously were compared between groups using discriminant analysis (Wilk's λ). We ran general linear models GLM with time and species as categorical independent variables ('factor'). As a measure of effect sizes we included partial eta-squared values (η2) i.e. the proportion of the effect+error variance that is attributable to the effect. The sums of the η2 values are not additive [e.g. [60]]. Normality was tested by Kolmogorov-Smirnov-tests and visual inspection. Only prion winter data (adult feathers) were not normally distributed. This was due to outliers (5 of 62 data points), and we therefore followed the suggestion of [61] and considered the test results only significant when P < 0.01. Otherwise, significance was assumed at P < 0.05, and means are given with standard errors.

Historical samples

Pools of fossil CO2 are depleted in 13C compared to CO2 in the atmosphere. The burning of large amounts of fossil CO2 has diluted the atmospheric CO2 pool resulting in a more negative δ13C value. This has been termed the Suess effect [7]. The increasing concentration of CO2 in the atmosphere has also resulted in an increasing concentration of dissolved CO2 in the ocean, resulting in increasing δ13C values in phytoplankton during the last 150 years. When long time series of δ13C are analysed, the data have to be corrected for the Suess effect [7]. We normalized all data to the current end of our database, the year 2008, by subtracting a year-specific factor δ13C = -1+ 1.1 (2008-year)*0.027[7]. It should be noted that the effect is small compared to the large range of δ13C values observed here. For example, the estimated overall Suess effect from 1850 to 2002 is 0.62‰ for Falkland Island waters.

Rising sea surface temperatures reduce the amount of dissolved CO2 in the ocean, termed CO2(aq). Because δ13C in phytoplankton is negatively correlated with CO2(aq) [30], this leads to a minor enrichment of 13C, e.g. for the period 1850-2002 a maximum correction factor of 0.16‰ was modelled [7]. Because of this small influence, we did not correct for sea surface temperature variation.

References

  1. Newton I: The migration ecology of birds. 2007, Oxford, UK, Elsevier

    Google Scholar 

  2. Hobson KA, Wassernaar LI: Tracking animal migration with stable isotopes. 2008, Amsterdam, Academic Press

    Google Scholar 

  3. Thompson DR, Furness RW, Lewis SA: Diets and long-term changes in δ15 N and δ13 C values in northern fulmars Fulmarus glacialis from two northeast Atlantic colonies. Mar Ecol Prog Ser. 1995, 125: 3-11. 10.3354/meps125003.

    Article  CAS  Google Scholar 

  4. Becker BH, Beissinger SR: Centennial decline in the trophic level of an endangered seabird after fisheries decline. Cons Biol. 2006, 20: 470-479. 10.1111/j.1523-1739.2006.00379.x.

    Article  Google Scholar 

  5. Norris DR, Arcese P, Preikshot D, Bertram DF, Kyser TK: Diet reconstruction and historic population dynamics in a threatened seabird. J Appl Ecol. 2007, 44: 875-884. 10.1111/j.1365-2664.2007.01329.x.

    Article  Google Scholar 

  6. Thompson DR, Sagar P: Declining rockhopper penguin populations in New Zealand. Water Atmosph. 2002, 10: 10-12.

    Google Scholar 

  7. Hilton GM, Thompson DR, Sagar PM, Cuthbert RJ, Cherel Y, Bury SJ: A stable isotopic investigation into the causes of decline in a sub-Antarctic predator, the rockhopper penguin Eudyptes chrysocome. Global Change Biol. 2006, 12: 611-625. 10.1111/j.1365-2486.2006.01130.x.

    Article  Google Scholar 

  8. Rau GH, Takahashi T, Des Marais DJ, Sullivan CW: Particulate organic matter δ13C variations across the Drake Passage. J Geophys Res. 1991, 96: 15131-15135. 10.1029/91JC01253.

    Article  CAS  PubMed  Google Scholar 

  9. Quillfeldt P, McGill RAR, Furness RW: Diet and foraging areas of Southern Ocean seabirds and their prey inferred from stable isotopes: review and case study of Wilson's storm-petrel. Mar Ecol Prog Ser. 2005, 295: 295-304. 10.3354/meps295295.

    Article  CAS  Google Scholar 

  10. Quillfeldt P, McGill RAR, Strange IJ, Masello JF, Weiss F, Brickle P, Furness RW: Stable isotope analysis reveals sexual and environmental variability and individual consistency in foraging of Thin-billed Prions. Mar Ecol Prog Ser. 2008, 373: 137-148. 10.3354/meps07751.

    Article  Google Scholar 

  11. Cherel Y, Hobson KA: Geographical variation in carbon stable isotope signatures of marine predators: a tool to investigate their foraging areas in the Southern Ocean. Mar Ecol Prog Ser. 2007, 329: 281-287. 10.3354/meps329281.

    Article  CAS  Google Scholar 

  12. Cherel Y, Bocher P, De Broyer C, Hobson KA: Food and feeding ecology of the sympatric thin-billed Pachyptila belcheri and Antarctic P. desolata prions at Iles Kerguelen, Southern Indian Ocean. Mar Ecol Prog Ser. 2002, 228: 263-281. 10.3354/meps228263.

    Article  Google Scholar 

  13. Cherel Y, Phillips RA, Hobson KA, McGill R: Stable isotope evidence of diverse species-specific and individual wintering strategies in seabirds. Biol Letters. 2006, 2: 301-303. 10.1098/rsbl.2006.0445.

    Article  CAS  Google Scholar 

  14. Gladbach A, McGill RAR, Quillfeldt P: Foraging areas of Wilson's storm-petrel Oceanites oceanicus in the breeding and inter-breeding period determined by stable isotope analysis. Polar Biol. 2007, 30: 1005-1012. 10.1007/s00300-007-0258-2.

    Article  Google Scholar 

  15. Quillfeldt P: Seasonal and annual variation in the diet of breeding and non-breeding Wilson's storm-petrels on King George Island, South Shetland Islands. Polar Biol. 2002, 25: 216-221.

    Google Scholar 

  16. Strange IJ: The thin-billed prion, Pachyptila belcheri, at New Island, Falkland Islands. Gerfaut. 1980, 70: 411-445.

    Google Scholar 

  17. Sánchez RP, de Ciechomski JD: Spawning and nursery grounds of pelagic fish species in the sea-shelf off Argentina and adjacent areas. Scientia Marina. 1995, 59: 455-478.

    Google Scholar 

  18. Bugoni L, Mancini PL, Monteiro DS, Nascimento L, Neves TS: Seabird bycatch in the Brazilian pelagic longline fishery and a review of capture rates in the southwestern Atlantic Ocean. Endang Species Res. 2008, 5: 137-147. 10.3354/esr00115.

    Article  Google Scholar 

  19. Ramírez FC, Viñas MD: Hyperiid amphipods found in Argentine shelf waters. Physis (Buenos Aires) Secc A. 1985, 43: 25-37.

    Google Scholar 

  20. Sabatini M, Martos P: Mesozooplankton features in a frontal area off northern Patagonia (Argentina) during spring 1995 and 1998. Scientia Marina. 2002, 66: 215-232. 10.3989/scimar.2002.66n3215.

    Article  Google Scholar 

  21. Bearhop S, Fielder W, Furness RW, Votier SC, Waldron S, Newton J, Bowen GJ, Berthold P, Farnsworth K: Assortative mating as a mechanism for rapid evolution of a migratory divide. Science. 2005, 310: 502-504. 10.1126/science.1115661.

    Article  CAS  PubMed  Google Scholar 

  22. Quillfeldt P, Voigt CC, Masello JF: Plasticity versus repeatability in seabird migratory behaviour. Behav Ecol Sociobiol. 2010,

    Google Scholar 

  23. Powlesland RG: Seabirds found dead on New Zealand beaches in 1986 and a review of Pachyptila species recoveries since 1960. Notornis. 1989, 36: 125-140.

    Google Scholar 

  24. Ryan PG, Avery G, Rose B, Ross GJB, Sinclair JC, Vernon CJ: The Southern Ocean seabird irruption to South African waters during winter 1984. Cormorant. 1989, 17: 41-55.

    Google Scholar 

  25. Martuscelli P, Silva e Silva R, Olmos F: A large Prion Pachyptila wreck in south-east Brazil. Cotinga. 1997, 8: 55-57.

    Google Scholar 

  26. Ainley DG, Jacobs SS, Ribic CA, Gaffney I: Seabird distribution and oceanic features of the Amundsen and southern Bellingshausen seas. Antarct Sci. 1998, 10: 111-123. 10.1017/S0954102098000169.

    Article  Google Scholar 

  27. Cherel Y, Bocher P, Trouvé C, Weimerskirch H: Diet and feeding ecology of blue petrels Halobaena caerulea at Iles Kerguelen, Southern Indian Ocean. Mar Ecol Prog Ser. 2002, 228: 283-299. 10.3354/meps228283.

    Article  Google Scholar 

  28. Harrison P: Seabirds - an identification guide. 1985, London: Christopher Helm

    Google Scholar 

  29. Dehairs F, Kopczynska E, Nielsen P, Lancelot C, Bakker DCE, Koeve W, Goeyens L: δ13C of Southern Ocean suspended organic matter during spring and early summer: regional and temporal variability. Deep Sea Res II. 1997, 4: 129-142. 10.1016/S0967-0645(96)00073-2.

    Article  Google Scholar 

  30. Francois R, Altabet MA, Goericke R, McCorkle DC, Brunet C, Poisson A: Changes in the δ13C of surface water particulate organic matter across the subtropical convergence in the SW Indian Ocean. Global Biogeochem Cycles. 1993, 7: 627-644. 10.1029/93GB01277.

    Article  CAS  Google Scholar 

  31. Bentaleb I, Fontugne M, Descolas-Gros C, Girardin C, Mariotti A, Pierre C, Brunet C, Poisson A: Carbon isotopic fractionation by plankton in the Southern Indian Ocean: relationship between delta C-13 of particulate organic carbon and dissolved carbon dioxide. J Mar Syst. 1998, 17: 39-58. 10.1016/S0924-7963(98)00028-1.

    Article  Google Scholar 

  32. Davenport SR, Bax NJ: A trophic study of a marine ecosystem off southeastern Australia using stable isotopes of carbon and nitrogen. Can J Fish Aquat Sci. 2002, 59: 514-530. 10.1139/f02-031.

    Article  Google Scholar 

  33. Eadie BJ, Jeffrey LM: δ13C analyses of oceanic particulate organic matter. Mar Chem. 1973, 1: 199-209. 10.1016/0304-4203(73)90004-2.

    Article  CAS  Google Scholar 

  34. Fischer G, Müller P, Wefer G: Latitudinal δ13C (org) variations in sinking matter and sediments from the South Atlantic: effects of anthropogenic CO2 and implications for paleo-PCO2 reconstructions. J Mar Syst. 1998, 17: 471-495. 10.1016/S0924-7963(98)00059-1.

    Article  Google Scholar 

  35. Fontugne M, Duplessy JC: Carbon isotope ratio of marine plankton related to surface water masses. Earth Planetary Sci Letters. 1978, 41: 365-371. 10.1016/0012-821X(78)90191-7.

    Article  CAS  Google Scholar 

  36. Frazer TK: Stable isotope composition (δ13C and δ15N) of larval krill, Euphausia superba, and two of its potential food sources in winter. J Plankton Res. 1996, 18: 1413-1426. 10.1093/plankt/18.8.1413.

    Article  CAS  Google Scholar 

  37. Hückstädt LA, Rojas CP, Antezana T: Stable isotope analysis reveals pelagic foraging by the Southern sea lion in central Chile. J Exp Mar Biol Ecol. 2007, 347: 123-133. 10.1016/j.jembe.2007.03.014.

    Article  Google Scholar 

  38. Kaehler S, Pakhomov EA, McQuaid CD: Trophic structure of the marine food web at the Prince Edward Islands (Southern Ocean) determined by δ13C and δ15N analysis. Mar Ecol Prog Ser. 2000, 208: 13-20. 10.3354/meps208013.

    Article  Google Scholar 

  39. Schmidt K, Atkinson A, Stubing D, McClelland JW, Montoya JP, Voss M: Trophic relationships among Southern Ocean copepods and krill: Some uses and limitations of a stable isotope approach. Limnol Oceanogr. 2003, 48: 277-289.

    Article  Google Scholar 

  40. Wada E, Terazaki M, Kabaya Y, Nemoto T: 15N and 13C abundances in the Antarctic Ocean with emphasis on the biogeochemical structure of the food web. Deep Sea Res. 1987, 34: 829-841. 10.1016/0198-0149(87)90039-2.

    Article  CAS  Google Scholar 

  41. Sackett WM, Eckelmann WR, Bender ML, Be AWH: Temperature dependence of carbon isotope composition in marine plankton and sediments. Science. 1965, 148: 235-10.1126/science.148.3667.235.

    Article  CAS  PubMed  Google Scholar 

  42. Cherel Y: Isotopic niches of emperor and Adelie penguins in Adelie Land, Antarctica. Mar Biol. 2008, 154: 813-821. 10.1007/s00227-008-0974-3.

    Article  Google Scholar 

  43. Corbisier TN, Petti MAV, Skowronski RSP, Brito TAS: Trophic relationships in the nearshore zone of Martel Inlet (King George Island, Antarctica): δ13C stable-isotope analysis. Polar Biol. 2004, 27: 75-82. 10.1007/s00300-003-0567-z.

    Article  Google Scholar 

  44. Dunton KH: δ15N and δ13C measurements of Antarctic peninsula fauna: Trophic relationships and assimilation of benthic seaweeds. Am Zool. 2001, 41: 99-112. 10.1668/0003-1569(2001)041[0099:NACMOA]2.0.CO;2.

    Google Scholar 

  45. Hall-Aspland SA, Rogers TL, Canfield RB: Stable carbon and nitrogen isotope analysis reveals seasonal variation in the diet of leopard seals. Mar Ecol Prog Ser. 2005, 305: 249-259. 10.3354/meps305249.

    Article  CAS  Google Scholar 

  46. Mizutani H, Wada E: Nitrogen and carbon isotope ratios in seabird rookeries and their ecological implications. Ecology. 1988, 69: 340-349. 10.2307/1940432.

    Article  Google Scholar 

  47. Thompson DR, Furness RW: Stable-isotope ratios of carbon and nitrogen in feathers indicate seasonal dietary shifts in northern Fulmars. Auk. 1995, 112: 493-498.

    Article  Google Scholar 

  48. Tierney M, Southwell C, Emmerson LM, Hindell MA: Evaluating and using stable-isotope analysis to infer diet composition and foraging ecology of Adélie penguins Pygoscelis adeliae. Mar Ecol Prog Ser. 2008, 355: 297-307. 10.3354/meps07235.

    Article  Google Scholar 

  49. Burns JM, Trumble SJ, Castellini MA, Testa JW: The diet of Weddell seals in McMurdo Sound, Antarctica as determined from scat collections and stable isotope analysis. Polar Biol. 1998, 19: 272-282. 10.1007/s003000050245.

    Article  Google Scholar 

  50. Cherel Y, Hobson KA, Weimerskirch H: Using stable-isotope analysis of feathers to distinguish moulting and breeding origins of seabirds. Oecologia. 2000, 122: 155-162. 10.1007/PL00008843.

    Article  Google Scholar 

  51. Forero MG, Bortolotti GR, Hobson KA, Donazar JA, Bertelloti M, Blanco G: High trophic overlap within the seabird community of Argentinean Patagonia: a multiscale approach. J Anim Ecol. 2004, 73: 789-801. 10.1111/j.0021-8790.2004.00852.x.

    Article  Google Scholar 

  52. Zimmer I, Piatkowski U, Brey T: The trophic link between squid and the emperor penguin Aptenodytes forsteri at Pointe Geologie, Antarctica. Mar Biol. 2007, 152: 1187-1195. 10.1007/s00227-007-0766-1.

    Article  Google Scholar 

  53. Hahn S, Peter H-U, Quillfeldt P, Reinhardt K: The birds of the Potter Peninsula, King George Island, South Shetland Islands, 1965-1998. Mar Orn. 1998, 26: 1-6.

    Google Scholar 

  54. Quillfeldt P: Wilson's storm-petrel. Encyclopedia of the Antarctic. Edited by: Riffenburgh B. 2007, New York: Routledge, 1081-1084.

    Google Scholar 

  55. Gladbach A, Büßer C, Mundry R, Quillfeldt P: Acoustic parameters of begging calls indicate chick body condition and influence parental feeding decisions in Wilson's storm-petrels Oceanites oceanicus. J Ethol. 2009, 27: 267-274. 10.1007/s10164-008-0115-y.

    Article  Google Scholar 

  56. Quillfeldt P, Bugoni L, McGill RAR, Masello JF, Furness RW: Differences in stable isotopes in blood and feathers of seabirds are consistent across species, age and latitude - implications for food web studies. Mar Biol. 2008, 155: 593-598. 10.1007/s00227-008-1048-2.

    Article  CAS  Google Scholar 

  57. Bridge ES: Influences of morphology and behavior on wing-molt strategies in seabirds. Mar Orn. 2006, 34: 7-19.

    Google Scholar 

  58. Mizutani H, Fukuda M, Kabaya Y: C-13 enrichment and N-15 enrichment factors of feathers of 11 species of adult birds. Ecology. 1992, 73: 1391-1395. 10.2307/1940684.

    Article  Google Scholar 

  59. Paritte JM, Kelly JF: Effect of cleaning regime on stable-isotope ratios of feathers in Japanese quail (Coturnix japonica). Auk. 2009, 126: 165-174. 10.1525/auk.2009.07187.

    Article  Google Scholar 

  60. Effect size (ES). [http://web.uccs.edu/lbecker/SPSS/glm_effectsize.htm]

  61. Zöfel P: Statistik verstehen. Ein Begleitbuch zur computergestützten Anwendung. 2002, München: Addison-Wesley

    Google Scholar 

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Acknowledgements

We gratefully acknowledge logistic support from New Island Conservation Trust (Ian Strange), Falkland Islands Government, Alfred-Wegner-Institut Bremerhaven, Instituto Antártico Argentino, Friedrich-Schiller-Universität Jena (Hans-Ulrich Peter) and Nancy Clum (WCS). Anja Gladbach, Felix Weiss and Amanda Duckworth helped preparing samples, and museum curators kindly provided samples (Buenos Aires: Pablo Tubaro, Wien: Ernst Bauernfeind, Anita Gamauf, Hamburg: Cordula Bracker, Cornell: Kimberly Bostwick, Leiden: Hein van Grouw, Porto Alegre: Emilio Antônio Jeckel Neto, Carla Suertegaray Fontana) or access to the collections (New York: Paul Sweet, Margaret Hart, La Plata: Carlos Darrieu). Gerhard Fischer provided a dataset used in the isoscape. Stable isotope analyses were funded by NERC (UK). PQ received funding for the fieldwork from Deutsche Forschungsgemeinschaft, Germany (Qu 148). The visit to the Tring collections was fundend by the European Union (SYNTHESYS GB-TAF-4731). We are grateful to three anonymous referees who provided helpful comments.

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PQ, JFM, and RWF planned and carried out the study. RARMcG conducted the stable isotope analyses at the NERC Life Sciences Mass Spectrometry Facility, MA facilitated access to museums and hosted a Synthesys-funded museum study. PQ drafted the manuscript. All authors read and approved the final manuscript.

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Quillfeldt, P., Masello, J.F., McGill, R.A. et al. Moving polewards in winter: a recent change in the migratory strategy of a pelagic seabird?. Front Zool 7, 15 (2010). https://doi.org/10.1186/1742-9994-7-15

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