About the Authors:
Raül Ramos
* E-mail: [email protected]
Affiliation: Eco-Ethology Research Unit, Instituto Superior de Psicologia Aplicada, Lisboa, Portugal
José Pedro Granadeiro
Affiliation: Centre for Environmental and Marine Studies, Museu Nacional de História Natural e da Ciência, Universidade de Lisboa, Lisboa, Portugal
Marie Nevoux
Affiliation: Mammal Research Institute, Department of Zoology and Entomology, University of Pretoria, Hatfield, South Africa
Jean-Louis Mougin
Affiliation: Laboratoire de Zoologie, Muséum National d’Histoire Naturelle, Paris, France
Maria Peixe Dias
Affiliation: Eco-Ethology Research Unit, Instituto Superior de Psicologia Aplicada, Lisboa, Portugal
Paulo Catry
Affiliation: Eco-Ethology Research Unit, Instituto Superior de Psicologia Aplicada, Lisboa, Portugal
Introduction
Understanding population dynamics of long-lived marine vertebrates is essential to identify relevant human impacts for the sustainability of our oceans [1], [2]. Due to the complexity of their annual cycles, this knowledge is particularly important for long-distance migrants as these anthropogenic threats might impact them over a larger geographical range, while breeding, migrating or at their wintering grounds [3], [4].
We have now clear evidences that human activities and resulting global changes are strongly impacting marine ecosystems [2], [5], [6]. A major threat for marine top predators is the increasing industrial fisheries occurring in most of our oceans [7], [8]. Effects of these fisheries on apical species may be negative, increasing incidental mortality [9]–[11], impoverishing food webs and reducing fish stocks [12], but also positive either directly through discards which provide additional food [13], [14] or indirectly by removing larger predatory fish (i.e. competitors). From the conservation point of view, fishery sustainability represents a sensitive, socio-economic issue and data regarding these collateral effects on marine top predators is scarce and poorly reported by the competent authorities [15]–[17], generating a poor knowledge on the real impact of commercial fisheries on marine megafauna. Global warming is also inducing changes in the distribution and abundance of marine prey and will therefore affect the dynamics of their predators [18]–[21]. Several long-term studies have documented links between climate and population dynamics through both local fluctuations in oceanographic parameters (e.g. sea surface temperature, SST; [22]) and large-scale cyclic patterns (e.g. Southern Oscillation Index, SOI; [23], [24]). The fact that the increasing global warming especially impacts polar environments [25], [26], might bias the bulk of climate-induced demography research towards Arctic and Antarctic species. In this sense, little is known about the potential effects of local and large-scale climatic phenomena on the productivity of temperate to tropical oceanic water masses.
Assessing the precise interactions between these changes and marine predator dynamics will therefore be critical for effective conservation management. In this sense, long-lived predator species are rather the most endangered and sensitive group of animals to environmental perturbation due to their extreme life history traits (e.g. high survival, low fecundity and an usually considerable degree of specialization; [9], [27]). Moreover, migratory predators, inhabiting very different water masses throughout their annual cycles, are particularly challenging in this respect (e.g. [28]). For instance, environmental conditions could have a strong impact on these migratory species not only at the breeding grounds but also along their migration routes or at their wintering grounds, when individuals from a variety of breeding origins congregate into common migratory corridors and wintering areas. Hence, the ability to identify and quantify the respective roles of climate and human activities in both breeding and wintering grounds of these long-lived top predators is important in the field of marine biological conservation.
The sophistication of statistical modelling techniques and the increasing availability of environmental data makes possible to integrate both climate and human effects on powerful demographic models to ultimately build realistic scenarios of the impact of future environmental changes on populations of marine organisms (e.g. [29], [30]). Spatio-temporal impacts of harmful processes on population dynamics have been studied in large marine species (e.g. albatrosses and marine mammals), but this has seldom been done in smaller migratory predators despite the fact they might be highly relevant in explaining energy flow and food web structuring in marine environments [31]–[33]. In addition, precise movements and foraging locations for these highly mobile predators are often unknown, notably in winter when many of these species remain unavailable to most researchers very far from their breeding colonies. In this sense, the Cory’s shearwater (Calonectris diomedea) represents a good model species as (1) it is a medium-sized long-lived marine top predator, (2) it breeds colonially at temperate to sub-tropical latitudes, (3) it carries out an annual trans-equatorial migration, (4) its survival is known to be affected by climate [34]–[37], and (5) several of its populations may be threatened by longline fisheries [38]. We took advantage of a capture-recapture monitoring carried out on the world’s largest colony of Cory’s shearwater over 34 years (from 1978 to 2011, with an in-between four-years gap), (a) to model its adult survival and (b) to assess the potential effects of fishery activity and (c) climate fluctuations on this long-lived migratory predator. More novelty, in order to select the most appropriate environmental variables that should be tested as candidate predictors of survival, detailed information on spatial and temporal distribution of the study population was obtained along four years by tracking 100 of their long-distance migrations.
Methods
Study Site and Data Collection
The island of Selvagem Grande (30°09′N, 15°52′W; Fig. 1) holds the largest known breeding colony of Cory’s shearwater in the world [39]. There are some historical records of its exploitation at this remote location, with Cory’s shearwater eggs and chicks being intensively exploited for food, oil and feathers through the first two thirds of the 20th century [40]. Constant harvests of chicks but also a few severe killings of adults in the 1970’s, reduced this population from ca. 100,000 breeding pairs (crude estimations at the beginning of the 20th century) to only 5,000 pairs in 1977 [41]. Since then, and due to the establishment of the Selvagens Islands Nature Reserve and a permanent vigilance, the shearwater population has increased and was estimated at ca. 29,540 breeding pairs in 2005 (Fig. 2; [39]). During the breeding season (March-October), Cory’s shearwaters from Selvagem Grande forage to a large extent in the Canary Current, along the Moroccan and Western Sahara coast where productivity is high, owing to the enrichment of the surface waters by a strong upwelling [42], [43]. Most of these trans-equatorial migratory shearwaters congregate in the South Atlantic Ocean during the non-breeding season (November-February), the Benguela Current being one of the most used wintering sites [44], [45].
[Figure omitted. See PDF.]
Figure 1. Distribution of Cory’s shearwaters from Selvagem Grande Island (star) throughout the annual cycle.
Schematic annual phenology (starting 1st January) and annual distribution of 100 Cory’s shearwaters tracked with geolocators between 2006 and 2009. Coloured areas encompass bird positions during the breeding and wintering seasons (in orange and dark blue, respectively) and the overall distribution during the migration periods (i.e., when commuting between breeding and wintering areas; in light blue). The main wintering areas were associated with Benguela and Agulhas Currents (n = 72 individuals), central South Atlantic (n = 11), Brazil-Malvinas confluence region (n = 8), northwest Atlantic (n = 4) and Canary Current (n = 5). Estimated proportion of time spent in each area by the whole adult population is shown in white panels. Note that the Canary Current includes all breeding positions as well as the few wintering ones. Photo credit R. Ramos.
https://doi.org/10.1371/journal.pone.0040822.g001
[Figure omitted. See PDF.]
Figure 2. Estimated breeding population of Cory’s shearwaters at Selvagem Grande Island along the sampled period.
Data from Mougin et al. 2000 and Granadeiro et al. 2006. Photo credit R. Ramos.
https://doi.org/10.1371/journal.pone.0040822.g002
Each year since the 1978 breeding season, new individuals found nesting at study sites within the colony and all their chicks were ringed with a monel band. The presence/absence of each ringed individual in the colony was recorded annually from 1978 by consecutive burrow visits during early incubation (early June). The analysed dataset is composed by (1) a continuous period of 22 years monitoring data (from 1978 to 1999) from a sample of ca. 500 individually numbered nests (3,227 individuals), and, (2) a period of eight years (from 2004 to 2011) coming from a different sample of 358 numbered nests (1,330 individuals), with no data collected in-between.
Tracking Data
Additionally, to choose the most appropriate and relevant environmental predictors for Cory’s shearwater survival, we first characterized the phenology and annual distribution of birds breeding at Selvagem Grande Island. We tracked their trans-equatorial migrations by deploying leg-mounted 3.6-g geolocators (mk7 model, developed by British Antarctic Survey, [46]) at the end of breeding seasons 2006, 2007, 2008 and 2009 (August/September). In the beginning of the following breeding seasons (April/June), we recovered complete data from 100 geolocators. Geolocators provide two positions per day based on light levels (one at local midday and other at local midnight), with an accuracy of approximately 186±114 km [47]. Data were analysed using TransEdit (to check for integrity of light curves and to fit dawn and dusk times; [46]) and Birdtrack software (to estimate the latitude from day length and longitude from the time of local midday relative to Greenwich Mean; [46]). We assumed a sun elevation angle of −4.5 degrees, based on known positions obtained during ground-truthing of loggers carried out before and after deployment. Unrealistic positions (those resulting from interference of light curves at dawn or dusk, or around equinox periods) were removed from the analyses.
Environmental and Fishery Data
We chose a series of climatic and fishery-related indices with biological interest for Cory’s shearwaters to explore their relationship with adult survival (Table 1). We extracted monthly values of all indices specifically for the Canary Current (20°–35°N, 10°–20°W) to evaluate their effect on the breeding ground, and for the Benguela (15°–40°S, 5°–25°E) and Agulhas (15°–40°S, 25°–45°E) Currents to assess their impact on the non-breeding grounds as described by tracking data (Fig. 1 and Appendix S1). In order to integrate the breeding and non-breeding periods separately, we averaged monthly data over April-September and December-February, respectively.
[Figure omitted. See PDF.]
Table 1. Questions addressed concerning the impact of fisheries and climate on Cory’s shearwater survival.
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In most cases, fishery-related indices are expected to affect directly adult survival, with longlining affecting negatively seabirds through incidental bycatch (e.g. [48], [49]). In particular, foraging areas exploited by Cory’s shearwater both in breeding and wintering periods are thought to largely overlap with areas frequented by longlining fishery vessels [38], [50], [51]. Thus, we tested the effect of longlining effort (LL) by extracting the number of hooks used by tuna longliners in specific areas and seasons (Appendix S1). Longlining data was obtained from International Commission for the Conservation of Atlantic Tunas (ICCAT) website (http://www.iccat.es/en/accesingdb.htm), which offers small scale (5°×5° squares) monthly catch and fishing effort indices.
Climatic fluctuations are also suspected to affect seabird mortality either directly through storminess (e.g. [34]), or after a temporal lag through an indirect mechanism (e.g. [52]), where climate first affects primary production, and then integrates along the trophic web up to top predators [53]. Firstly, we explored potential effects of the Southern Oscillation Index (SOI, available at http://www.esrl.noaa.gov/psd/data/correlation/soi.data), which reflects El Niño/La Niña large-scale oscillations through changes in sea level pressure between the south-eastern and south-western Pacific waters. Although the effect of the SOI is most pronounced in the south-eastern Pacific Ocean, other southern marine ecosystems such as the Southern Atlantic where most Cory’s shearwaters winter seem also affected by sustained positive SOI values (i.e. La Niña episodes; [54]). Secondly, we tested a local index, the Sea Surface Temperature (SST, available at http://badc.nerc.ac.uk/view/badc.nerc.ac.uk_ATOM_dataent_hadisst, at 1° spatial resolution, HadISST 1.1; Hadley Centre, British Atmospheric Data Centre), which provides information on oceanographic conditions on a finer geographical scale and which may ultimately structure the trophic web. Finally, we considered both SOI and SST variables lagged one (breeding to non-breeding, or vice versa), two (i.e. one entire year), three or even four seasons (see Appendix S1 for details). By these means, we investigated the potential long-lasting effects of these environmental variables through the whole trophic web on survival.
To reduce the number of explanatory variable and avoid spurious relationships (errors of type I, [55]), we either combined correlated variables of the same nature (i.e. units) by averaging all respective months (e.g. SST in the breeding ground for four consecutive seasons and SOI for the non-breeding and the previous breeding seasons) or we performed a Principal Component Analyses (PCA) when the correlated variables were of a different nature (e.g. LL with all SST in the non-breeding grounds). We retained the first and second PCs for that last synthetic covariate (denoted by PC1LLSST and PC2LLSST, respectively) which accounted for 47.7% and 28.8% of the variation of the four original covariates, respectively. This reduced set of six variables is detailed in Appendix S1.
Demographic Modelling
Demographic parameters were estimated with capture-mark-recapture (CMR; [56]) models, using M-Surge version 1.8 [57] and a total of 4,555 adult capture-recapture histories, over the 1978–2011 period. We started with the Cormarck-Jolly-Seber (CJS) model where survival (Φ, probability that a shearwater alive at year t survives at year t+1) and capture (p, probability that a shearwater alive and present at the breeding colony at year t is caught during the year t) were time (t) and group (sex) dependent. The fit of the general model to the data was investigated with goodness-of-fit (GOF) tests for each period (1978–99 and 2004–11) and sex using program U-Care version 2.2 [58]. Model selection was done using the Akaike Information Criterion corrected for small sample size and overdispersion (QAICc; [59]). When comparing two models, if ΔQAICc >2, the preferred model is the one with the smallest QAICc value (i.e. the most parsimonious model in terms of the number of parameters and model deviance; [56]). Along the modelling, capture probability was fixed to zero for the period 2000–2003 in all the individuals, and for the period 2004–2011 in those individuals sampled during the first period (i.e. 1978–1999) to account for changes in the monitoring protocol over the course of the study. To test and evaluate the impact of (uncorrelated) climate and fishery covariates on adult survival, we progressively built models from the best time dependent model including one covariate at a time. We started testing the potential linear effect of longline fisheries (direct mortality) on survival and we then tested for linear and non-linear (quadratic) effects of the climate on seabird demography. We also tested whether the impact of each of these covariates was constant over the entire period 1978–2011 (one slope) or whether it differed between 1978–1999 and 2004–2011 periods (two slopes). By doing so, we aimed to disentangle whether these variables had changed their potential effect between the two considered periods. The ability of each covariate to describe significant variation in survival was assessed using analysis of deviance tests (ANODEV: F-test statistic with ncov and n-ncov-1degrees of freedom, where ncov represented the number of covariates included and n was the number of parameters of the time dependent model; [60]) and the effects of these covariates were quantified using an approximated R2statistic [61]: R2 = DEV(Mcst)-DEV(Mcov)/[DEV(Mcst)-DEV(Mt)], where DEV(Mcst), DEV(Mcov) and DEV(Mt) are the respective deviances for the models constant, with covariate(s) and time dependent. While modelling the effect of the covariates, Mcst were selected according to the aim of the test (see Table 3 for details).
Results
Annual Phenology and Distribution Gathered from Geolocator Data
Movements of tracked Cory’s shearwaters were easily classified into frequent foraging trips around the breeding colony (including the Canary Current), rapid, long-distance migratory movements, and persistent presence in a well defined non-breeding ground, by combining location data and date. Most birds wintered in five broad areas (Fig. 1), associated with the Benguela and Agulhas Currents (72% of the individuals), central South Atlantic (11%), the Brazilian Current (8%), northwest Atlantic (4%) and the Canary Current (5%). On average, they left the colony the first fortnight of November (mean departure date: 5 November+/−14 days), and took 36 days to reach their major destination (mean arrival date: 11 December+/−17 days). Birds left their non-breeding areas around mid-February (19 February+/−9 days) and arrived at Selvagem Grande three weeks later (14 March+/−11 days). Overall, Cory’s shearwaters from Selvagem Island spend 66.3% of their annual time in the breeding grounds, only 13.8% of the time migrating and 19.9% in one of their non-breeding areas, mainly in the South Atlantic Ocean (Fig. 1). Later, these dates, time expenditure and precise locations along the year allowed us defining precise spatio-temporal delimitations of several environmental indices which were likely to affect Cory’s shearwater survival.
Goodness of Fit Test
The GOF test indicated a severe lack of fit of the umbrella model (χ2316 = 1783.7, P<0.0001), coming from the presence of both transient and trap dependence effects [62]. The first effect suggested the presence of transients, i.e. prospecting or inexperienced animals from other locations, in both periods and sexes (test 3.SR in Table 2). Transience violates the CJS model assumption of equal survival between newly and previously marked individuals. In the case of high capture probabilities, transient individuals can be efficiently deleted by suppressing the first recapture of all animals [63], [64]. After doing so, test 3.SR was not significant anymore for any of the periods or sexes (Table 2). The positive trap-dependent effect (test 2.CT in Table 2), which indicates that individuals captured on one occasion were more likely to be captured on the following occasion than others was accounted by splitting capture-recapture histories (using U-Care software) and implementing a trap-dependence model (where capture probability results from a Markovian dependence on previous capture, denoted by m; [65]). Finally, our modelling based on Φsex*t pm*sex*t was also corrected with a variance inflation factor c-hat to take into account the remaining lack of fit (χ2203 = 354.7, P<0.0001), calculated as the χ2 statistic over its number of degrees of freedom (c-hat = 1.746; [56]).
[Figure omitted. See PDF.]
Table 2. Results of goodness-of-fit (GOF) tests of CJS model (Φt pt), for each period (1978–99 and 2004–11) and sex. individual was removed to account for transience.
https://doi.org/10.1371/journal.pone.0040822.t002
Estimating Demographic Parameters through the 1978–2011 Period
We started testing in the umbrella model (Φsex*t pm*sex*t) whether survival and capture probabilities varied with sex and/or time (Table 3). The lowest QAICc was obtained for a model with an additive effect of time on trap-dependence categories (additive trap effect) for capture probability and time-dependent survival (model 7; Fig. 3a). Survival probability was estimated as Φ = 0.915 (SE = 0.037, range = 0.909–0.921) from the constant model (model 8). We then assessed the effect of covariates using the model structure of that selected time-dependent model as a starting point (model 7; Table 3). Searching for direct causes of mortality (models 9–14), we detected a significant negative effect of the longlining effort on the Canary Current during the breeding period on survival (LLCCbr, model 9, ANODEV = 5.772, PANODEV = 0.024), explaining 20.8% of the variation. We then tested for potential additive effects of climatic parameters on Cory’s shearwater survival (models 15–26): in model 15, we noted a significant negative impact of SST in the Canary Current on survival estimates (SSTCC2yr, ANODEV = 6.623, PANODEV = 0.005) although in model 18, a more significant negative effect of annual SOI was found impacting on survival parameters (SOIyr, ANODEV = 7.937, PANODEV = 0.002, R2 = 0.425). In model 24, additively to LLCCbr and SOIyr, the integrative covariate of SST of the Canary Current was still affecting seabird demography (SSTCC2yr, ANODEV = 3.984, PANODEV = 0.021, R2 = 0.498; Fig. 3). The relevance of both climatic variables was more apparent when they were considered in a linear trend, suggesting therefore weak non-linear effects of climate on Cory’s shearwater survival (models 16, 19 and 25). In addition, none of the models including different slopes for 1980–1999 and 2005–2011 periods were preferred when tested against the model with a single slope (although models 10 and 20 were close to), suggesting similar effects of the covariates along the two periods. Finally, none of the confidence intervals of the selected covariates included zero, suggesting that all three covariates, i.e. LLCCbr, SOIyr and SSTCC2yr contributed negatively and significantly (−0.104±0.040, −0.212±0.081, −0.137±0.058, respectively) to year-to-year variations in survival throughout the period 1980–2011 (Fig. 4).
[Figure omitted. See PDF.]
Table 3. Modelling capture (p) and survival (φ) probabilities in the Cory’s shearwater breeding at Selvagem Grande Island and the effects of covariates on survival.
https://doi.org/10.1371/journal.pone.0040822.t003
[Figure omitted. See PDF.]
Figure 3. Annual variation of adult survival probabilities and the selected covariates for the period 1980–2011.
Variation in survival rates of adults (a) and the selected covariates: (b) longlining effort in the Canary Current during the breeding, (c) annual SOI and (d) SST in the Canary Current (2 years averaged) are shown separately. Survival estimates come from the time-dependent model (Φt pm+t; in black dots and CI in solid bars) and from the selected model with the covariates (ΦLLccbr+SOIyr+SSTcc2yr pm+t; in dense dashed line and CI in light dashed lines).
https://doi.org/10.1371/journal.pone.0040822.g003
[Figure omitted. See PDF.]
Figure 4. Relationship between annual adult survival probabilities and the selected covariates from the best CMR model.
(a) Longlining effort in the Canary Current during the breeding, (b) annual SOI and (c) SST in the Canary Current (2 years averaged) are depicted against survival estimates (mean in black dots and asymmetric CI in solid bars estimated from the model Φt pm+t). Regression lines estimated from model 24 in Table 3.
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Discussion
The present study revealed that combined effects of climate and fishery activities in both breeding and non-breeding areas impacted negatively on the survival of a long-lived migratory seabird. Interestingly, tracking data of a hundred individuals allowed us to estimate that Cory’s shearwaters breeding at Selvagens Islands spend two thirds of the year mainly feeding in the Canary Current while breeding, and the other third migrating toward very restricted areas of the Southern Atlantic Ocean (Fig. 1). These precise spatio-temporal schedules along the entire year achieved by tracking devices became clue in selecting and delimiting specific environmental variables and potential anthropogenic threats, and ultimately allowed us to relate these precise covariates to the demography of this highly pelagic seabird.
Modelling Demography of a Long-lived Migratory Seabird
Marine top predators, such as the Cory’s shearwater, are considered extreme K-selected species, which means that their specific life history traits, long life expectancy, delayed maturity and low reproductive rates are unavoidably linked to high adult survival [27]. Using CMR analysis we found that estimated adult survival of this mid-sized Procellariiform seabird (0.915±0.037 on average, from the model Φ. pm+t) was low compared with other Atlantic colonies (>0.93; [34], [66]), but higher than in Mediterranean populations (ranging from 0.82 to 0.90; [34], [36], [37], [67]). Survival of Cory’s shearwaters breeding at Selvagens Islands was negatively affected by a combined effect of environmental variables and fishery effort at different points of their annual life cycle. Our models reported evidence that greater longlining activity and La Niña events increased shearwater mortality in breeding and non-breeding grounds, respectively (Fig. 4). Temperature variation in the Canary Current apparently also affected negatively shearwater survival probability, although likely through an indirect effect mediated through the trophic web on which the birds depend.
Longlining has a harmful effect on the entire marine ecosystem, with significant implication for the non-targeted top predators [9]–[11]. During line setting of thousands of baited hooks, seabirds (among other marine top predators) are particularly prone to be accidentally caught while scavenging on bait, being dragged under water afterwards and finally drowned. In the Mediterranean, longlining activity is thought to be responsible for large population declines of Cory’s shearwaters at several breeding colonies [68], [69], while in the Southern Atlantic (and for extension in the entire Atlantic) Cory’s shearwater incidental bycatch was thought to occur very scarcely [50], [66], [70]–[72]. However, our results suggested that incidental mortality may have been overlooked in Atlantic waters, i.e. that longlining activity might have not only affected Mediterranean birds, but also have affected the survival of Atlantic Cory’s shearwaters (see also [51]). We suggest that the short time spent by this migratory seabird outside its breeding areas decreases the probability to be caught (as well as observed) in the Southern Atlantic Ocean, where most bycatch research has been done. Thus, Cory’s shearwater may be threatened by commercial fisheries all along its distribution, although higher impacts probably occurred at the breeding grounds [38], [73], where shearwaters spend two thirds of their annual cycle (Fig. 1).
Adult survival of Cory’s shearwaters was also negatively affected by SOI (Fig. 4b). Typically, local manifestations of the Southern Oscillation are expected to influence Cory’s shearwater wintering grounds in the Southern Atlantic, where birds spend the short non-breeding season (Fig. 1). Sustained positive values of the SOI are characterized by tropical storms and hurricanes in the Atlantic (i.e. extreme La Niña events; [23]) which have long been related to several mass mortalities and breeding failures of many marine top predators in the Southern Ocean [20], [54], [74], including seabirds in the Benguela upwelling system [75]. Indeed, our results corroborated the findings of others, which suggested that during La Niña years the greater storminess of the Southern Atlantic may cause a decrease in Cory’s shearwater survivorship [34]–[37]. Although most of these studies considered that these climate effects acted directly on winter mortality, indirect effects of SOI on wintering grounds through a trophic cascade cannot be ruled out.
In addition to longliner activity, warm sea surface temperatures around the Canary Current during the current year and the year before a given breeding period also predicted low adult survival (Fig. 4c) during the long breeding season. Although high SST has been previously found affecting negatively several seabird populations (e.g. [76]–[78]), the fact that this effect is lagged supports the idea that it is not temperature per se, but a mediated effect, presumably through the food web, which might trigger seabird mortality [12], [79]. Indeed, some evidence of delayed effects of SST on the trophic web of the Canary Current have been previously reported at lower trophic levels (e.g. the 6 months delay between plankton and sardine recruitment [80], [81]). Several oceanographic factors, such as positive SST values negatively influence the abundance of plankton, which in turn plays a key role in fish recruitment [82]–[84]. Thus, a reduction in productivity would decrease fish abundance, constraining the foraging opportunities of birds, and therefore increasing Cory’s shearwater mortality rate (e.g. [12], [79], [85]).
The Selvagem’s Perspective
Cory’s shearwaters of Macaronesian Islands were exploited by indigenous inhabitants from prehistoric times (e.g. [86], [87]). More recently, regular chick harvest, with likely increasing intensity during most of the 20th century, plus severe episodes of adult killings reduced dramatically the population of Selvagem Island [41]. Fortunately, after enhanced protection since the late 1970’s, the number of breeding birds built up rapidly, at ca. 30% per year in the early 1980’s, mainly due to the progressive recruitment of large numbers of non-breeding individuals that survived the 1975 and 1976 culls (Fig. 2; [41]). Survival estimates for that period remained relatively high and rather stable (i.e. 0.92±0.01 in 1980–1986, see Fig. 3a), which contributed to the rapid recovery of the nesting numbers. From 1987 to 1995, survival rates oscillated year-to-year, and the population growth stabilized at an average rate of 5% per year, with an estimated population of 18,100 breeding pairs in 1995 [88]. However, from that point and at least until the end of the century (i.e., 1999), survival estimates dropped to 0.86±0.02 on average, and in 1998 the numbers apparently reduced to 15,750 breeding pairs (Fig. 2; [89]), a reduction of over 13% in three years. The decrease in survival probability along this period coincides with an elevated number of hooks used by longliners in the Canary Current (Fig. 3b), which could be contributing to the significance of this covariate in our modelling. After an unknown gap of four years, Cory’s shearwater survival rates for 2005–2011 somewhat recovered (0.91±0.02) and the population apparently resumed its growth, reaching up to around 30,000 breeding pairs in 2005 (Fig. 2; [39]), and making Selvagem Grande the largest world colony of Cory’s shearwaters. Furthermore, the longliner activity in the Canary Current region seems to have decreased considerably during the last decade (Fig 3b), which may have positively contributed to the recovery of the population throughout this last period. Hence, though the Cory’s shearwater population from the Selvagens is still far from its presumed size at the beginning of the 20th century, the evidence of a recovery process is very clear. However, predicted climate change and the resulting global warming could still have a negative impact both in breeding and non-breeding grounds, and continued monitoring of the dynamics of this population may be relevant to understand future trends.
Conclusions
High adult survival and low fecundity are typical of long-lived species, and even small reductions in survival can have dramatic effects on population trends. Although survival rates reported for Cory’s shearwaters breeding at Selvagem Grande were generally higher and more stable than in most other colonies, particularly those in the Mediterranean, the amount of variation in survival explained by climatic and human-related variables was high (49.8%), considering the long period analysed. The survival of this species was moderately influenced by longlining activity and more markedly by climatic factors. Although it was encouraging that tuna longlining fishing effort declined over the last decade in the Canary Current, our results highlight the need for more research on fisheries impact on sea life in the subtropical Northeast Atlantic, where very few studies have been conducted. The results of this study also warn to the negative effects of climate at both breeding (SST) and non-breeding grounds (SOI), and it is clear that these could be aggravated in the near future, given that inter-annual variation in SST and the virulence of El Niño/La Niña events are expected to further increase [26].
From the conservation point of view, the negative impact of both longline fisheries and raised SST in the Canary Current possibly does not only concern locally breeding Cory’s shearwaters, but also wintering shearwaters from both Atlantic and Mediterranean populations that use this Current [44], [45], [90]–[92], as well as many other species inhabiting this restricted upwelling area of the subtropical Atlantic [93]–[96]. However, in terms of magnitude, the storminess generated by El Niño/La Niña phenomena in the Southern Atlantic Ocean seems to have a higher impact in the survival of Cory’s shearwaters than the effects occurring in the Canary Current. In fact, although it only represents 20% of their annual cycle, events occurring during the non-breeding period may be highly relevant for the population dynamics of Cory’s shearwaters. Overall, our results contributed to highlight the importance of considering not only breeding grounds, but also precise schedules and places visited while non-breeding for the appropriate understanding of impacts of the environment on the population dynamics of long-distance migratory species.
Ethics Statement
All animals were handled in strict accordance with good animal practice as defined by the current European legislation. The deployment of MK7 loggers (see details above) did not take more than 10 minutes and on no occasion did it interfere with reproduction or have visible deleterious effects on study animals [97]. All work was approved by Instituto da Conservação da Natureza e da Biodiversidade and Serviço do Parque Natural da Madeira, where Selvagens Islands Nature Reserve belongs to (research permits 107/2006, 116/2007, 333/2007/CAPT).
Supporting Information
[Figure omitted. See PDF.]
Appendix S1.
Correlations among the explanatory covariates. Pearson’s coefficients are placed below the diagonal and P-values of a t-test above the diagonal. Shaded areas highlight three sets of correlated covariates: a) sea surface temperatures (SST) in the breeding ground (4 consecutive periods averaged, SSTCC2yr), b) longlining effort (LL) and SST (3 consecutive periods) in the non-breeding grounds (first and second principal components (PC) explaining respectively 47.7 and 28.8% of covariate variability), and c) Southern Oscillation Index (SOI) in two consecutive periods (current non-breeding and previous breeding periods, SOIyr). Bold type highlights the covariates retained for the analysis of survival and the correlations among them.
https://doi.org/10.1371/journal.pone.0040822.s001
(DOC)
Acknowledgments
Parque Natural da Madeira, and particularly Paulo Oliveira, Dília Menezes and Carolina Santos, provided permissions to carry out the work and, together with the wardens at the Nature Reserve where this study took place, gave important logistical support. Teresa Catry, Hany Alonso, Ana Almeida, Rafael Matias, Miguel Lecoq, Rui Rebelo and others helped with fieldwork. We also thank our colleague Ana Sanz for her helpful suggestions on an earlier draft of the manuscript.
Author Contributions
Conceived and designed the experiments: RR JPG PC. Performed the experiments: RR JPG JLM MPD PC. Analyzed the data: RR JPG MN MPD PC. Contributed reagents/materials/analysis tools: JPG PC. Wrote the paper: RR JPG MN MPD PC.
Citation: Ramos R, Granadeiro JP, Nevoux M, Mougin J-L, Dias MP, Catry P (2012) Combined Spatio-Temporal Impacts of Climate and Longline Fisheries on the Survival of a Trans-Equatorial Marine Migrant. PLoS ONE 7(7): e40822. https://doi.org/10.1371/journal.pone.0040822
1. Wooller RD, Bradley JS, Croxall JP (1992) Long-term population studies of seabirds. Trends in Ecology & Evolution 7: 111–114.RD WoollerJS BradleyJP Croxall1992Long-term population studies of seabirds.Trends in Ecology & Evolution7111114
2. Lotze HK, Coll M, Magera AM, Ward-Paige C, Airoldi L (2011) Recovery of marine animal populations and ecosystems. Trends in Ecology & Evolution 26: 595–605.HK LotzeM. CollAM MageraC. Ward-PaigeL. Airoldi2011Recovery of marine animal populations and ecosystems.Trends in Ecology & Evolution26595605
3. Marra PP, Norris DR, Haig SM, Webster MS, Royle JA (2006) Migratory connectivity. In: Crooks KR, Sanjayan MA, editors. pp. 157–183.PP MarraDR NorrisSM HaigMS WebsterJA Royle2006Migratory connectivity.KR CrooksMA Sanjayan157183editors.Connectivity conservation.New York, USA: Cambridge University Press. New York, USA: Cambridge University Press.
4. Martin TG, Chadès I, Arcese P, Marra PP, Possingham HP, et al. (2007) Optimal conservation of migratory species. PLoS ONE 2: e751.TG MartinI. ChadèsP. ArcesePP MarraHP Possingham2007Optimal conservation of migratory species.PLoS ONE2e751
5. Halpern BS, Walbridge S, Selkoe KA, Kappel CV, Micheli F, et al. (2008) A global map of human impact on marine ecosystems. Science 319: 948–952.BS HalpernS. WalbridgeKA SelkoeCV KappelF. Micheli2008A global map of human impact on marine ecosystems.Science319948952
6. Heithaus MR, Frid A, Wirsing AJ, Worm B (2008) Predicting ecological consequences of marine top predator declines. Trends in Ecology & Evolution 23: 202–210.MR HeithausA. FridAJ WirsingB. Worm2008Predicting ecological consequences of marine top predator declines.Trends in Ecology & Evolution23202210
7. Pauly D, Watson R, Alder J (2005) Global trends in world fisheries: impacts on marine ecosystems and food security. Philosophical Transactions of the Royal Society B: Biological Sciences 360: 5–12.D. PaulyR. WatsonJ. Alder2005Global trends in world fisheries: impacts on marine ecosystems and food security.Philosophical Transactions of the Royal Society B: Biological Sciences360512
8. Jackson JBC (2008) Ecological extinction and evolution in the brave new ocean. Proceedings of the National Academy of Sciences of the United States of America 105: 11458–11465.JBC Jackson2008Ecological extinction and evolution in the brave new ocean.Proceedings of the National Academy of Sciences of the United States of America1051145811465
9. Lewison RL, Crowder LB, Read AJ, Freeman SA (2004) Understanding impacts of fisheries bycatch on marine megafauna. Trends in Ecology & Evolution 19: 598–604.RL LewisonLB CrowderAJ ReadSA Freeman2004Understanding impacts of fisheries bycatch on marine megafauna.Trends in Ecology & Evolution19598604
10. BirdLife International (2008) State of the world’s birds: indicators for our changing world. Cambridge, UK: BirdLife International. International BirdLife2008State of the world’s birds: indicators for our changing world.Cambridge, UK: BirdLife International
11. Read AJ, Drinker P, Northridge S (2006) Bycatch of marine mammals in U. S. and global fisheries. Conservation Biology 20: 163–169.AJ ReadP. DrinkerS. Northridge2006Bycatch of marine mammals in U. S. and global fisheries.Conservation Biology20163169
12. Frederiksen M, Edwards M, Richardson AJ, Halliday NC, Wanless S (2006) From plankton to top predators: bottom-up control of a marine food web across four trophic levels. Journal of Animal Ecology 75: 1259–1268.M. FrederiksenM. EdwardsAJ RichardsonNC HallidayS. Wanless2006From plankton to top predators: bottom-up control of a marine food web across four trophic levels.Journal of Animal Ecology7512591268
13. Oro D, Cam E, Pradel R, Martínez-Abraín A (2004) Influence of food availability on demography and local population dynamics in a long-lived seabird. Proceedings of the Royal Society B: Biological Sciences 271: 387–396.D. OroE. CamR. PradelA. Martínez-Abraín2004Influence of food availability on demography and local population dynamics in a long-lived seabird.Proceedings of the Royal Society B: Biological Sciences271387396
14. Bunce A, Norman FI, Brothers N, Gales R (2002) Long-term trends in the Australasian gannet (Morus serrator) population in Australia: the effect of climate change and commercial fisheries. Marine Biology 141: 263–269.A. BunceFI NormanN. BrothersR. Gales2002Long-term trends in the Australasian gannet (Morus serrator) population in Australia: the effect of climate change and commercial fisheries.Marine Biology141263269
15. Watson R, Pauly D (2001) Systematic distortions in world fisheries catch trends. Nature 414: 534–536.R. WatsonD. Pauly2001Systematic distortions in world fisheries catch trends.Nature414534536
16. Bearzi G, Politi E, Agazzi S, Azzellino A (2006) Prey depletion caused by overfishing and the decline of marine megafauna in eastern Ionian Sea coastal waters (central Mediterranean). Biological Conservation 127: 373–382.G. BearziE. PolitiS. AgazziA. Azzellino2006Prey depletion caused by overfishing and the decline of marine megafauna in eastern Ionian Sea coastal waters (central Mediterranean).Biological Conservation127373382
17. Jacquet J, Pauly D (2008) Trade secrets: renaming and mislabeling of seafood. Marine Policy 32: 309–318.J. JacquetD. Pauly2008Trade secrets: renaming and mislabeling of seafood.Marine Policy32309318
18. Hughes L (2000) Biological consequences of global warming: is the signal already. Trends in Ecology & Evolution 15: 56–61.L. Hughes2000Biological consequences of global warming: is the signal already.Trends in Ecology & Evolution155661
19. Richardson AJ, Schoeman DS (2004) Climate impact on plankton ecosystems in the Northeast Atlantic. Science 305: 1609–1612.AJ RichardsonDS Schoeman2004Climate impact on plankton ecosystems in the Northeast Atlantic.Science30516091612
20. Le Bohec C, Durant M, Gauthier-Clerc M, Stenseth NC, Park Y-H, et al. (2008) King penguin population threatened by Southern Ocean warming. Proceedings of the National Academy of Sciences of the United States of America 105: 2493–2497.C. Le BohecM. DurantM. Gauthier-ClercNC StensethY-H Park2008King penguin population threatened by Southern Ocean warming.Proceedings of the National Academy of Sciences of the United States of America10524932497
21. Wells BK, Field JC, Thayer JA, Grimes CB, Bograd SJ, et al. (2008) Untangling the relationships among climate, prey and top predators in an ocean ecosystem. Marine Ecology Progress Series 364: 15–29.BK WellsJC FieldJA ThayerCB GrimesSJ Bograd2008Untangling the relationships among climate, prey and top predators in an ocean ecosystem.Marine Ecology Progress Series3641529
22. Jenouvrier S, Barbraud C, Weimerskirch H (2005) Long-term contrasted responses to climate of two Antarctic seabird species. Ecology 86: 2889–2903.S. JenouvrierC. BarbraudH. Weimerskirch2005Long-term contrasted responses to climate of two Antarctic seabird species.Ecology8628892903
23. Stenseth NC, Ottersen G, Hurrell JW, Mysterud A, Lima M, et al. (2003) Studying climate effects on ecology through the use of climate indices: the North Atlantic Oscillation, El Niño Southern Oscillation and beyond. Proceedings of the Royal Society B: Biological Sciences 270: 2087–2096.NC StensethG. OttersenJW HurrellA. MysterudM. Lima2003Studying climate effects on ecology through the use of climate indices: the North Atlantic Oscillation, El Niño Southern Oscillation and beyond.Proceedings of the Royal Society B: Biological Sciences27020872096
24. Nevoux M, Weimerskirch H, Barbraud C (2007) Environmental variation and experience-related differences in the demography of the long-lived black-browed albatross. Journal of Animal Ecology 76: 159–167.M. NevouxH. WeimerskirchC. Barbraud2007Environmental variation and experience-related differences in the demography of the long-lived black-browed albatross.Journal of Animal Ecology76159167
25. Clarke A, Harris CM (2003) Polar marine ecosystems: major threats and future change. Environmental Conservation 30: 1–25.A. ClarkeCM Harris2003Polar marine ecosystems: major threats and future change.Environmental Conservation30125
26. IPCC (2007) Climate change 2007: The physical science basis. Contribution of working group I to the fourth assessment report of the intergovernmental panel on climate change. Solomon S, Qin D, Manning M, Chen Z, Marquis M, et al., editors New York, USA: Cambridge University Press. IPCC2007Climate change 2007: The physical science basis. Contribution of working group I to the fourth assessment report of the intergovernmental panel on climate change.Solomon S, Qin D, Manning M, Chen Z, Marquis M, et al., editors New York, USA: Cambridge University Press
27. Gaston AJ (2004) Birth and death: Theory. In: Seabirds: A Natural History. New Haven, Connecticut: Yale University Press. pp. 162–171.AJ Gaston2004Birth and death: Theory.In: Seabirds: A Natural History. New Haven, Connecticut: Yale University Press.162171
28. Phillips RA, Silk JRD, Croxall JP, Afanasyev V, Bennett VJ (2005) Summer distribution and migration of nonbreeding albatrosses: individual consistencies and implications for conservation. Ecology 86: 2386–2396.RA PhillipsJRD SilkJP CroxallV. AfanasyevVJ Bennett2005Summer distribution and migration of nonbreeding albatrosses: individual consistencies and implications for conservation.Ecology8623862396
29. Barbraud C, Rivalan P, Inchausti P, Nevoux M, Weimerskirch H (2011) Contrasted demographic responses facing future climate change in Southern Ocean seabirds. Journal of Animal Ecology 80: 89–100.C. BarbraudP. RivalanP. InchaustiM. NevouxH. Weimerskirch2011Contrasted demographic responses facing future climate change in Southern Ocean seabirds.Journal of Animal Ecology8089100
30. Jenouvrier S, Caswell H, Barbraud C, Holland M, Strœve J, et al. (2009) Demographic models and IPCC climate projections predict the decline of an emperor penguin population. Proceedings of the National Academy of Sciences of the United States of America 106: 1844–1847.S. JenouvrierH. CaswellC. BarbraudM. HollandJ. Strœve2009Demographic models and IPCC climate projections predict the decline of an emperor penguin population.Proceedings of the National Academy of Sciences of the United States of America10618441847
31. Croxall JP (1987) Seabirds: feeding ecology and role in marine ecosystems. Cambridge, UK: Cambridge University Press. JP Croxall1987Seabirds: feeding ecology and role in marine ecosystems.Cambridge, UK: Cambridge University Press
32. Guinet C, Cherel Y, Ridoux V, Jouventin P (1996) Consumption of marine resources by seabirds and seals in Crozet and Kerguelen waters: changes in relation to consumer biomass. Antarctic Science 8: 23–30.C. GuinetY. CherelV. RidouxP. Jouventin1996Consumption of marine resources by seabirds and seals in Crozet and Kerguelen waters: changes in relation to consumer biomass.Antarctic Science82330
33. Overholtz WJ, Link JS (2007) Consumption impacts by marine mammals, fish, and seabirds on the Gulf of Maine, Georges Bank Atlantic herring (Clupea harengus) complex during the years 1977–2002. ICES Journal of Marine Science 64: 83–96.WJ OverholtzJS Link2007Consumption impacts by marine mammals, fish, and seabirds on the Gulf of Maine, Georges Bank Atlantic herring (Clupea harengus) complex during the years 1977–2002.ICES Journal of Marine Science648396
34. Jenouvrier S, Thibault J-C, Viallefont A, Vidals P, Ristow D, et al. (2009) Global climate patterns explain range-wide synchronicity in survival of a migratory seabird. Global Change Biology 15: 268–279.S. JenouvrierJ-C ThibaultA. ViallefontP. VidalsD. Ristow2009Global climate patterns explain range-wide synchronicity in survival of a migratory seabird.Global Change Biology15268279
35. Brichetti P, Foschi UF, Boano G (2000) Does El Nino affect survival rate of Mediterranean populations of Cory’s shearwater? Waterbirds 23: 147–154.P. BrichettiUF FoschiG. Boano2000Does El Nino affect survival rate of Mediterranean populations of Cory’s shearwater?Waterbirds23147154
36. Boano G, Brichetti P, Foschi UF (2010) “La Nina”-driven Atlantic storms affect winter survival of Mediterranean Cory’s Shearwaters. Italian Journal of Zoology 77: 460–468.G. BoanoP. BrichettiUF Foschi2010“La Nina”-driven Atlantic storms affect winter survival of Mediterranean Cory’s Shearwaters.Italian Journal of Zoology77460468
37. Ristow D, Feldmann F, Scharlau W, Wink M (1990) Population structure, philopatry and mortality of Cory’s shearwater Calonectris d. diomedea. Vogelwelt 111: 172–181.D. RistowF. FeldmannW. ScharlauM. Wink1990Population structure, philopatry and mortality of Cory’s shearwater Calonectris d. diomedea.Vogelwelt111172181
38. Cooper J, Baccetti N, Belda EJ, Borg JJ, Oro D, et al. (2003) Seabird mortality from longline fishing in the Mediterranean Sea and Macaronesian waters: a review and a way forward. Scientia Marina 67: 57–64.J. CooperN. BaccettiEJ BeldaJJ BorgD. Oro2003Seabird mortality from longline fishing in the Mediterranean Sea and Macaronesian waters: a review and a way forward.Scientia Marina675764
39. Granadeiro JP, Dias MP, Rebelo R, Santos CD, Catry P (2006) Numbers and population trends of Cory’s shearwater Calonectris diomedea at Selvagem Grande, Northeast Atlantic. Waterbirds 29: 56–60.JP GranadeiroMP DiasR. RebeloCD SantosP. Catry2006Numbers and population trends of Cory’s shearwater Calonectris diomedea at Selvagem Grande, Northeast Atlantic.Waterbirds295660
40. Zino PA (1985) Pequeno apontamento histórico sobre a caça das cagarras na Selvagem Grande e desenvolvimentos recentes nesta ilha. Museu Municipal do Funchal, Bocagiana 84: 1–14.PA Zino1985Pequeno apontamento histórico sobre a caça das cagarras na Selvagem Grande e desenvolvimentos recentes nesta ilha.Museu Municipal do Funchal, Bocagiana84114
41. Mougin J-L, Jouanin C, Roux F (2000) Démographie du puffin cendré Calonectris diomedea de Selvagem Grande (30°09′ N, 15°52' W). Revue d’Ecologie (La Terre et la Vie) 55: 275–290.J-L MouginC. JouaninF. Roux2000Démographie du puffin cendré Calonectris diomedea de Selvagem Grande (30°09′ N, 15°52' W).Revue d’Ecologie (La Terre et la Vie)55275290
42. Mougin J-L, Jouanin C (1997) Prospection alimentaire du puffin cendré Calonectris diomedea borealis de Selvagem Grande (30°09′N, 15°52'W) pendant l'incubation, par télémétrie satellitaire. Comptes rendus de l’Académie des sciences Série 3, Sciences de la vie 320: 825–831.J-L MouginC. Jouanin1997Prospection alimentaire du puffin cendré Calonectris diomedea borealis de Selvagem Grande (30°09′N, 15°52'W) pendant l'incubation, par télémétrie satellitaire.Comptes rendus de l’Académie des sciences Série 3, Sciences de la vie320825831
43. Paiva VH, Geraldes P, Ramírez I, Meirinho A, Garthe S, et al. (2010) Oceanographic characteristics of areas used by Cory’s shearwaters during short and long foraging trips in the North Atlantic. Marine Biology 157: 1385–1399.VH PaivaP. GeraldesI. RamírezA. MeirinhoS. Garthe2010Oceanographic characteristics of areas used by Cory’s shearwaters during short and long foraging trips in the North Atlantic.Marine Biology15713851399
44. Dias MP, Granadeiro JP, Phillips RA, Alonso H, Catry P (2011) Breaking the routine: individual Cory’s shearwaters shift winter destinations between hemispheres and across ocean basins. Proceedings of the Royal Society B: Biological Sciences 278: 1786–1793.MP DiasJP GranadeiroRA PhillipsH. AlonsoP. Catry2011Breaking the routine: individual Cory’s shearwaters shift winter destinations between hemispheres and across ocean basins.Proceedings of the Royal Society B: Biological Sciences27817861793
45. González-Solís J, Croxall JP, Oro D, Ruiz X (2007) Trans-equatorial migration and mixing in the wintering areas of a pelagic seabird. Frontiers in Ecology and the Environment 5: 297–301.J. González-SolísJP CroxallD. OroX. Ruiz2007Trans-equatorial migration and mixing in the wintering areas of a pelagic seabird.Frontiers in Ecology and the Environment5297301
46. British Antarctic Survey (2008) Migrating bird tracking logger. In: In BAS Research: Instruments and Techniques. Cambridge: British Antarctic Survey. Survey British Antarctic2008Migrating bird tracking logger.In: In BAS Research: Instruments and Techniques. Cambridge: British Antarctic Surveyhttp://www.antarctica.ac.uk. http://www.antarctica.ac.uk.
47. Phillips RA, Silk JRD, Croxall JP, Afanasyev V, Briggs DR (2004) Accuracy of geolocation estimates for flying seabirds. Marine Ecology Progress Series 266: 265–272.RA PhillipsJRD SilkJP CroxallV. AfanasyevDR Briggs2004Accuracy of geolocation estimates for flying seabirds.Marine Ecology Progress Series266265272
48. Weimerskirch H, Capdeville D, Duhamel G (2000) Factors affecting the number and mortality of seabirds attending trawlers and long-liners in the Kerguelen area. Polar Biology 23: 236–249.H. WeimerskirchD. CapdevilleG. Duhamel2000Factors affecting the number and mortality of seabirds attending trawlers and long-liners in the Kerguelen area.Polar Biology23236249
49. Véran S, Gimenez O, Flint E, Kendall WL, Doherty Jr PF, et al. (2007) Quantifying the impact of longline fisheries on adult survival in the black-footed albatross. Journal of Applied Ecology 44: 942–952.S. VéranO. GimenezE. FlintWL KendallJr PF Doherty2007Quantifying the impact of longline fisheries on adult survival in the black-footed albatross.Journal of Applied Ecology44942952
50. Olmos F (1997) Seabirds attending bottom long-line fishing off southeastern Brazil. Ibis 139: 685–691.F. Olmos1997Seabirds attending bottom long-line fishing off southeastern Brazil.Ibis139685691
51. Berrow SD (1993) Cory’s shearwater taking tuna lure. Irish Birds 5: 78.SD Berrow1993Cory’s shearwater taking tuna lure.Irish Birds578
52. Barbraud C, Marteau C, Ridoux V, Delord K, Weimerskirch H (2008) Demographic response of a population of white-chinned petrels Procellaria aequinoctialis to climate and longline fishery bycatch. Journal of Applied Ecology 45: 1460–1467.C. BarbraudC. MarteauV. RidouxK. DelordH. Weimerskirch2008Demographic response of a population of white-chinned petrels Procellaria aequinoctialis to climate and longline fishery bycatch.Journal of Applied Ecology4514601467
53. Wilson C, Adamec D (2002) A global view of bio-physical coupling from SeaWiFS and TOPEX satellite data, 1997–2001. Geophysical Research Letters 29: 1–4.C. WilsonD. Adamec2002A global view of bio-physical coupling from SeaWiFS and TOPEX satellite data, 1997–2001.Geophysical Research Letters2914
54. Duffy DC Glynn PW, editor. (1990) Seabirds and the 1982–83 El Niño Southern Oscillation. Amsterdam, the Netherlands: Elsevier Oceanographic Series 52: 395–415.DC Duffy1990Seabirds and the 1982–83 El Niño Southern Oscillation.PW GlynnAmsterdam, the Netherlands: Elsevier Oceanographic Series52395415editor.Global ecological consequences of the 1982–1983 El Niño Southern Oscillation. Global ecological consequences of the 1982–1983 El Niño Southern Oscillation.
55. Grosbois V, Gimenez O, Gaillard JM, Pradel R, Barbraud C, et al. (2008) Assessing the impact of climate variation on survival in vertebrate populations. Biological Reviews 83: 357–399.V. GrosboisO. GimenezJM GaillardR. PradelC. Barbraud2008Assessing the impact of climate variation on survival in vertebrate populations.Biological Reviews83357399
56. Lebreton J-D, Burnham KP, Clobert J, Anderson DR (1992) Modeling survival and testing biological hypotheses using marked animals: a unified approach with case studies. Ecological Monographs 62: 67–118.J-D LebretonKP BurnhamJ. ClobertDR Anderson1992Modeling survival and testing biological hypotheses using marked animals: a unified approach with case studies.Ecological Monographs6267118
57. Choquet R, Reboulet A-M, Pradel R, Gimenez O, Lebreton J-D (2006) M-SURGE (Multi-state SURvival Generalized Estimation) 1.8 user’s manual. Montpellier, France: Centre d’Ecologie Fonctionnelle et Evolutive, CEFE-CNRS. R. ChoquetA-M RebouletR. PradelO. GimenezJ-D Lebreton2006M-SURGE (Multi-state SURvival Generalized Estimation) 1.8 user’s manual.Montpellier, France: Centre d’Ecologie Fonctionnelle et Evolutive, CEFE-CNRS
58. Choquet R, Reboulet A-M, Lebreton J-D, Gimenez O, Pradel R (2005) U-CARE (Utilities-CApture-REcapture) 2.2 User’s Manual. R. ChoquetA-M RebouletJ-D LebretonO. GimenezR. Pradel2005U-CARE (Utilities-CApture-REcapture) 2.2 User’s Manual.
59. Burnham KP, Anderson DR (1998) Model selection and model inference: a practical information-theoretic approach. KP BurnhamDR Anderson1998Model selection and model inference: a practical information-theoretic approach.2nd ed.New York, USA: Springer-Verlag. New York, USA: Springer-Verlag.
60. Lebreton J-D, Choquet R, Gimenez O (2011) Simple estimation and test procedures in capture-mark-recapture mixed models. Biometrics in press. J-D LebretonR. ChoquetO. Gimenez2011Simple estimation and test procedures in capture-mark-recapture mixed models.Biometrics in press
61. Skalski JR (1996) Regression of abundance estimates from mark-recapture surveys against environmental covariates. Canadian Journal of Fisheries and Aquatic Sciences 53: 196–204.JR Skalski1996Regression of abundance estimates from mark-recapture surveys against environmental covariates.Canadian Journal of Fisheries and Aquatic Sciences53196204
62. Pradel R, Gimenez O, Lebreton J-D (2005) Principles and interest of GOF tests for multistate capture-recapture models. Animal Biodiversity and Conservation 28: 189–204.R. PradelO. GimenezJ-D Lebreton2005Principles and interest of GOF tests for multistate capture-recapture models.Animal Biodiversity and Conservation28189204
63. Pradel R, Hines JE, Lebreton J-D, Nichols JD (1997) Capture-recapture survival models taking account of transients. Biometrics 53: 60–72.R. PradelJE HinesJ-D LebretonJD Nichols1997Capture-recapture survival models taking account of transients.Biometrics536072
64. Grosbois V, Harris MP, Anker-Nilssen T, McCleery RH, Shaw DN, et al. (2009) Modeling survival at multi-population scales using mark-recapture data. Ecology 90: 2922–2932.V. GrosboisMP HarrisT. Anker-NilssenRH McCleeryDN Shaw2009Modeling survival at multi-population scales using mark-recapture data.Ecology9029222932
65. Pradel R (1993) Flexibility in survival analysis from recapture data: handling trap-dependence. In: Lebreton J-D, North PM, editors. pp. 29–37.R. Pradel1993Flexibility in survival analysis from recapture data: handling trap-dependence.J-D LebretonPM North2937editors.Marked individuals in the study of bird population.Basel, Switzerland: Birkhaeuser-Verlag. Basel, Switzerland: Birkhaeuser-Verlag.
66. Fontaine R, Gimenez O, Bried J (2011) The impact of introduced predators, light-induced mortality of fledglings and poaching on the dynamics of the Cory’s shearwater (Calonectris diomedea) population from the Azores, northeastern subtropical Atlantic. Biological Conservation 144: 1998–2011.R. FontaineO. GimenezJ. Bried2011The impact of introduced predators, light-induced mortality of fledglings and poaching on the dynamics of the Cory’s shearwater (Calonectris diomedea) population from the Azores, northeastern subtropical Atlantic.Biological Conservation14419982011
67. Sanz-Aguilar A, Tavecchia G, Genovart M, Igual JM, Oro D, et al. (2011) Studying the reproductive skipping behavior in long-lived birds by adding nest inspection to individual-based data. Ecological Applications 21: 555–564.A. Sanz-AguilarG. TavecchiaM. GenovartJM IgualD. Oro2011Studying the reproductive skipping behavior in long-lived birds by adding nest inspection to individual-based data.Ecological Applications21555564
68. Belda EJ, Sánchez A (2001) Seabird mortality on longline fisheries in the western Mediterranean: factors affecting bycatch and proposed mitigating measures. Biological Conservation 98: 357–363.EJ BeldaA. Sánchez2001Seabird mortality on longline fisheries in the western Mediterranean: factors affecting bycatch and proposed mitigating measures.Biological Conservation98357363
69. Laneri K, Louzao M, Martínez-Abraín A, Arcos JM, Belda EJ, et al. (2010) Trawling regime influences longline seabird bycatch in the Mediterranean: new insights from a small-scale fishery. Marine Ecology Progress Series 420: 241–252.K. LaneriM. LouzaoA. Martínez-AbraínJM ArcosEJ Belda2010Trawling regime influences longline seabird bycatch in the Mediterranean: new insights from a small-scale fishery.Marine Ecology Progress Series420241252
70. Tuck GN, Polacheck T, Bulman CM (2003) Spatio-temporal trends of longline fishing effort in the Southern Ocean and implications for seabird bycatch. Biological Conservation 114: 1–27.GN TuckT. PolacheckCM Bulman2003Spatio-temporal trends of longline fishing effort in the Southern Ocean and implications for seabird bycatch.Biological Conservation114127
71. Anderson ORJ, Small CJ, Croxall JP, Dunn EK, Sullivan BJ, et al. (2011) Global seabird bycatch in longline fisheries. Endangered Species Research 14: 91–106.ORJ AndersonCJ SmallJP CroxallEK DunnBJ Sullivan2011Global seabird bycatch in longline fisheries.Endangered Species Research1491106
72. Bugoni L, Mancini PL, Monteiro DS, Nascimento L, Neves TS (2008) Seabird bycatch in the Brazilian pelagic longline fishery and a review of capture rates in the southwestern Atlantic Ocean. Endangered Species Research 5: 137–147.L. BugoniPL ManciniDS MonteiroL. NascimentoTS Neves2008Seabird bycatch in the Brazilian pelagic longline fishery and a review of capture rates in the southwestern Atlantic Ocean.Endangered Species Research5137147
73. Benjamins S, Kulka DW, Lawson J (2008) Incidental catch of seabirds in Newfoundland and Labrador gillnet fisheries, 2001–2003. Endangered Species Research 5: 149–160.S. BenjaminsDW KulkaJ. Lawson2008Incidental catch of seabirds in Newfoundland and Labrador gillnet fisheries, 2001–2003.Endangered Species Research5149160
74. Weimerskirch H, Inchausti P, Guinet C, Barbraud C (2003) Trends in bird and seal populations as indicators of a system shift in the Southern Ocean. Antarctic Science 15: 249–256.H. WeimerskirchP. InchaustiC. GuinetC. Barbraud2003Trends in bird and seal populations as indicators of a system shift in the Southern Ocean.Antarctic Science15249256
75. Barbraud C, Weimerskirch H (2001) Emperor penguins and climate change. Nature 411: 183–186.C. BarbraudH. Weimerskirch2001Emperor penguins and climate change.Nature411183186
76. Jenouvrier S, Barbraud C, Weimerskirch H (2003) Effects of climate variability on the temporal population dynamics of southern fulmars. Journal of Animal Ecology 72: 576–587.S. JenouvrierC. BarbraudH. Weimerskirch2003Effects of climate variability on the temporal population dynamics of southern fulmars.Journal of Animal Ecology72576587
77. Luczak C, Beaugrand G, Jaffré M, Lenoir S (2011) Climate change impact on Balearic shearwater through a trophic cascade. Biology Letters 7: 702–705.C. LuczakG. BeaugrandM. JaffréS. Lenoir2011Climate change impact on Balearic shearwater through a trophic cascade.Biology Letters7702705
78. Machu E, Ettahiri O, Kifani S, Benazzouz A, Makaoui A, et al. (2009) Environmental control of the recruitment of sardines (Sardina pilchardus) over the western Saharan shelf between 1995 and 2002: a coupled physical/biogeochemical modelling experiment. Fisheries Oceanography 18: 287–300.E. MachuO. EttahiriS. KifaniA. BenazzouzA. Makaoui2009Environmental control of the recruitment of sardines (Sardina pilchardus) over the western Saharan shelf between 1995 and 2002: a coupled physical/biogeochemical modelling experiment.Fisheries Oceanography18287300
79. Roy C, Cury P (2003) Decadal environmental and ecological changes in the Canary Current Large Marine Ecosystem and adjacent waters: patterns of connections and teleconnection. In: Sherman K, Hempel G, editors. pp. 255–277.C. RoyP. Cury2003Decadal environmental and ecological changes in the Canary Current Large Marine Ecosystem and adjacent waters: patterns of connections and teleconnection.K. ShermanG. Hempel255277editors.Large Marine Ecosystems of the world.Trends in exploitation, protection and research. Trends in exploitation, protection and research.
80. Hjermann DO, Stenseth NC, Ottersen G (2004) Indirect climatic forcing of the Barents Sea capelin: a cohort effect. Marine Ecology Progress Series 273: 229–238.DO HjermannNC StensethG. Ottersen2004Indirect climatic forcing of the Barents Sea capelin: a cohort effect.Marine Ecology Progress Series273229238
81. Santos AMP, Kazmin AS, Peliz Á (2005) Decadal changes in the Canary upwelling system as revealed by satellite observations: their impact on productivity. Journal of Marine Research 63: 359–379.AMP SantosAS KazminÁ. Peliz2005Decadal changes in the Canary upwelling system as revealed by satellite observations: their impact on productivity.Journal of Marine Research63359379
82. Shackell NL, Bundy A, Nye JA, Link JS (2012) Common large-scale responses to climate and fishing across Northwest Atlantic ecosystems. ICES Journal of Marine Science 69: 151–162.NL ShackellA. BundyJA NyeJS Link2012Common large-scale responses to climate and fishing across Northwest Atlantic ecosystems.ICES Journal of Marine Science69151162
83. Quillfeldt P, J. Strange I, F. Masello J (2007) Sea surface temperatures and behavioural buffering capacity in thin-billed prions Pachyptila belcheri: breeding success, provisioning and chick begging. Journal of Avian Biology 38: 298–308.P. QuillfeldtI. J. StrangeJ. F. Masello2007Sea surface temperatures and behavioural buffering capacity in thin-billed prions Pachyptila belcheri: breeding success, provisioning and chick begging.Journal of Avian Biology38298308
84. Croxall JP, Callaghan T, Cervellati R, Walton DWH (1992) Southern Ocean environmental changes: effects on seabird, seal and whale populations [and discussion]. Philosophical Transactions of the Royal Society B: Biological Sciences 338: 319–328.JP CroxallT. CallaghanR. CervellatiDWH Walton1992Southern Ocean environmental changes: effects on seabird, seal and whale populations [and discussion].Philosophical Transactions of the Royal Society B: Biological Sciences338319328
85. La Cock GD (1986) The Southern Oscillation, environmental anomalies, and mortality of two Southern African seabirds. Climatic Change 8: 173–184.GD La Cock1986The Southern Oscillation, environmental anomalies, and mortality of two Southern African seabirds.Climatic Change8173184
86. Rando JC, López M, Jiménez MC (1997) Bird remains from the archaeological site of Guinea (El Hierro, Canary Islands). International Journal of Osteoarchaeology 7: 298–302.JC RandoM. LópezMC Jiménez1997Bird remains from the archaeological site of Guinea (El Hierro, Canary Islands).International Journal of Osteoarchaeology7298302
87. Martin A, Nogales M, Quilis V, Delgado G, Hernandez E, et al. (1991) La colonie de puffin cendré (Calonectris diomedea) de l’ile d’Alegranza (Lanzarote/Iles Canaries). Boletim do Museu Munincipal do Funchal 43: 107–120.A. MartinM. NogalesV. QuilisG. DelgadoE. Hernandez1991La colonie de puffin cendré (Calonectris diomedea) de l’ile d’Alegranza (Lanzarote/Iles Canaries).Boletim do Museu Munincipal do Funchal43107120
88. Mougin J-L, Granadeiro JP, Oliveira P (1996) L’évolution des effectifs des reproducteurs chez le Puffin cendré Calonectris diomedea borealis de Selvagem Grande (30°09′N, 15°52′W) de 1992 à 1995. Boletim do Museu Munincipal do Funchal 269: 171–178.J-L MouginJP GranadeiroP. Oliveira1996L’évolution des effectifs des reproducteurs chez le Puffin cendré Calonectris diomedea borealis de Selvagem Grande (30°09′N, 15°52′W) de 1992 à 1995.Boletim do Museu Munincipal do Funchal269171178
89. Mougin J-L, Mougin M-C (2000) L’evolution des effectifs des Puffin cendrés Calonectris diomedea borealis de l’ile Selvagem Grande (30°09′N, 15°52′W) de 1995 à 1998. Boletim do Museu Munincipal do Funchal 52: 45–50.J-L MouginM-C Mougin2000L’evolution des effectifs des Puffin cendrés Calonectris diomedea borealis de l’ile Selvagem Grande (30°09′N, 15°52′W) de 1995 à 1998.Boletim do Museu Munincipal do Funchal524550
90. Arcos JM, Bécares J, Rodríguez B, Ruiz A (2009) Important areas for the conservation of seabirds in Spain. Madrid, Spain: Sociedad Española de Ornitología. JM ArcosJ. BécaresB. RodríguezA. Ruiz2009Important areas for the conservation of seabirds in Spain.Madrid, Spain: Sociedad Española de Ornitología(SEO/Birdlife). (SEO/Birdlife).
91. Ramírez I, Geraldes P, Meirinho A, Amorim P, Paiva VH (2008) Important areas for seabirds in Portugal. Lisboa, Portugal: Sociedade Portuguesa Para o Estudo das Aves, SPEA. I. RamírezP. GeraldesA. MeirinhoP. AmorimVH Paiva2008Important areas for seabirds in Portugal.Lisboa, Portugal: Sociedade Portuguesa Para o Estudo das Aves, SPEA
92. Ristow D, Berthold P, Hashmi D, Querner U (2000) Satellite tracking of Cory’s shearwater migration. Condor 102: 696–699.D. RistowP. BertholdD. HashmiU. Querner2000Satellite tracking of Cory’s shearwater migration.Condor102696699
93. Wynn RB, Knefelkamp B (2004) Seabird ditribution and oceanic upwlling of northwest Africa. British Birds 97: 323–335.RB WynnB. Knefelkamp2004Seabird ditribution and oceanic upwlling of northwest Africa.British Birds97323335
94. Camphuysen KCJ, van der Meer J (2005) Wintering seabirds in West Africa: foraging hotspots off Western Sahara and Mauritania driven by upwelling and fisheries. African Journal of Marine Science 27: 427–437.KCJ CamphuysenJ. van der Meer2005Wintering seabirds in West Africa: foraging hotspots off Western Sahara and Mauritania driven by upwelling and fisheries.African Journal of Marine Science27427437
95. Oro D, Martínez-Vilalta A (1994) Migration and dispersal of Audouin’s gull Larus audouinii from the Ebro Delta colony. Ostrich 65: 225–230.D. OroA. Martínez-Vilalta1994Migration and dispersal of Audouin’s gull Larus audouinii from the Ebro Delta colony.Ostrich65225230
96. Stenhouse IJ, Egevang C, Phillips RA (2012) Trans-equatorial migration, staging sites and wintering area of Sabine’s Gulls Larus sabini in the Atlantic Ocean. Ibis 154: 42–51.IJ StenhouseC. EgevangRA Phillips2012Trans-equatorial migration, staging sites and wintering area of Sabine’s Gulls Larus sabini in the Atlantic Ocean.Ibis1544251
97. Igual JM, Forero MG, Tavecchia G, González-Solís J, Martínez-Abraín A, et al. (2005) Short-term effects of data-loggers on Cory’s shearwater (Calonectris diomedea). Marine Biology 146: 619–624.JM IgualMG ForeroG. TavecchiaJ. González-SolísA. Martínez-Abraín2005Short-term effects of data-loggers on Cory’s shearwater (Calonectris diomedea).Marine Biology146619624
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Abstract
Predicting the impact of human activities and their derivable consequences, such as global warming or direct wildlife mortality, is increasingly relevant in our changing world. Due to their particular life history traits, long-lived migrants are amongst the most endangered and sensitive group of animals to these harming effects. Our ability to identify and quantify such anthropogenic threats in both breeding and wintering grounds is, therefore, of key importance in the field of conservation biology. Using long-term capture-recapture data (34 years, 4557 individuals) and year-round tracking data (4 years, 100 individuals) of a trans-equatorial migrant, the Cory’s shearwater (Calonectris diomedea), we investigated the impact of longline fisheries and climatic variables in both breeding and wintering areas on the most important demographic trait of this seabird, i.e. adult survival. Annual adult survival probability was estimated at 0.914±0.022 on average, declining throughout 1978–1999 but recovering during the last decade (2005–2011). Our results suggest that both the incidental bycatch associated with longline fisheries and high sea surface temperatures (indirectly linked to food availability; SST) increased mortality rates during the long breeding season (March-October). Shearwater survival was also negatively affected during the short non-breeding season (December-February) by positive episodes of the Southern Oscillation Index (SOI). Indirect negative effects of climate at both breeding (SST) and wintering grounds (SOI) had a greater impact on survival than longliner activity, and indeed these climatic factors are those which are expected to present more unfavourable trends in the future. Our work underlines the importance of considering both breeding and wintering habitats as well as precise schedules/phenology when assessing the global role of the local impacts on the dynamics of migratory species.
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