Determining patterns of migratory connectivity for highly-mobile, wide-ranging species, such as sea turtles, is challenging. Here, we combined satellite telemetry and stable isotope analysis to estimate foraging locations for 749 individual loggerheads nesting along the east central Florida (USA) coast, the largest rookery for the Northwest Atlantic population. We aggregated individual results by year, identified seven foraging hotspots and tracked these summaries to describe the dynamics of inter-annual contributions of these geographic areas to this rookery over a nine-year period. Using reproductive information for a subset of turtles (n = 513), we estimated hatchling yields associated with each hotspots. We found considerable inter-annual variability in the relative contribution of foraging areas to the nesting adults. Also reproductive success differed among foraging hotspots; females using southern foraging areas laid nests that produced more offspring in all but one year of the study. These analyses identified two high priority areas for future research and conservation efforts: the continental shelf adjacent to east central Florida and the Great Bahama Bank, which support higher numbers of foraging females that provide higher rates of hatchling production. The implementation of the continuous-surface approach to determine geographic origins of unknown migrants is applicable to other migratory species.
Many marine species are difficult to study as they undertake ocean-wide developmental and breeding migrations during their life cycle1. Our understanding of the ecology of migrants that move between geographically distinct feeding and reproductive areas has been expanded by technological advances that are becoming progressively more affordable such as satellite telemetry, genetic markers and intrinsic markers [e.g., stable isotope analysis (SIA)2,3]. When these techniques are combined, they provide complementary information to unravel patterns associated with migratory connectivity4,5.
Sea turtles are long-living, late-maturing and highly migratory species of conservation concern that are primarily studied on nesting beaches where they are easily accessible. However, only a small portion of their complex life histories is spent in their breeding habitats. Reproductively active females undertake breeding migrations every 1 to 9+ years often from distant long-term residence areas (hereafter, foraging areas) to their natal nesting beach where they typically lay several clutches in a nesting season6.
Sea turtle status assessments and recovery plans7,8 rely heavily on long-term standardized annual nest counts. These are used as indirect indices of female abundance9. Even though nesting activities may have been monitored for decades, we cannot confidently identify the drivers of nest count trends because our understanding of demographic rates (i.e., breeding rates, clutch frequency) is imprecise and our characterization of the ecological context that influences demographic parameters (e.g., resource availability, temperature, oceanic current systems and oceanic productivity) is speculative10. Thus, abundance estimates, demographic parameters, genetic relationships among nesting populations, locations of commonly used foraging areas and related threats, effects of coastal and pelagic fisheries are critical data needs for sea turtle assessment and management10.
Satellite telemetry has contributed to understanding the spatial ecology of individual adult females and addressing some data needs by identifying foraging areas, migratory corridors and habitat use5,11. Though telemetry depicts detailed organism-level migratory paths, it is less suitable for understanding population-wide dynamics when individual movements are idiosyncratic, such as found with sea turtles, because typically only a few individuals are tracked in any given year due to high sensor costs, which can lead to biased or imprecise results. However, population-level questions can be addressed at a coarser spatial resolution using the comparatively cost-effective SIA, once the isotopic approach has been validated by satellite telemetry12,13,14. Stable isotopes are eco-geochemical markers that act as forensic recorders of migratory and foraging behaviors3. Tissue samples (e.g., egg-yolk, epidermis, red blood cells, scute, unhatched eggs) collected from nesting sea turtles represent an integration of diet and geographic location used prior to nesting15,16. The integration of these two approaches has augmented our knowledge of sea turtle migratory ecology12,17.
Post-nesting satellite-tracked females that migrate to different foraging areas can be identified by differences in their isotopic signatures. Adult females exhibit natal philopatry and fidelity to feeding areas throughout their adult life16,18,19. Thus, researchers have focused on sea turtle nesting aggregations by sampling nesting females and their nests and have used SIA to infer foraging areas of untracked individuals13,14,20,21,22. The potential of cost-effective SIA to elucidate nesting and in-water trends (e.g., changes in contribution of females from different foraging areas over time which may be related to differential survival probabilities at residence areas) has been denoted22,23,24. From isotopic signatures coupled with satellite geolocation data and in-water captures, researchers developed loggerhead-specific isoscapes (maps of stable isotope ratios) for the Northwest Atlantic (NWA) and found geographic discrimination in δ13C and δ15N suggesting that a spatially-explicit, continuous-surface approach may provide further insight into this species’ migratory patterns23. Isoscapes can be used to create geographic models for the probability of tissue origin25, which can in turn be used as a proxy of foraging locations. Population-level summaries of the probability models can help to identify foraging hotspots24.
We focused on loggerhead nesting at the Archie Carr National Wildlife Refuge (ACNWR), which accounts for ~14% of the nests laid by the NWA loggerhead rookery26, the largest subpopulation in the world7. Previous satellite tagging, flipper tag returns, and SIA have provided details on post-nesting female migration14,27,28 and which broad residence areas are used for foraging by this nesting aggregation13,22,29. However, a spatially-explicit approach has yet to be applied to infer origin of unknown (non-satellite tracked) high trophic level and migratory marine animals30. Here, we update previously developed isoscapes by including a larger number of known-origin (satellite-tracked) adult females and apply a continuous-surface likelihood approach to: 1) determine geographic histories for a large number of untagged nesting loggerheads; 2) identify geographic comparatively persistent foraging hotspots; 3) examine the dynamics of inter-annual contribution of foraging areas to this rookery over a nine-year period (2007–2015), and 4) evaluate geographic patterns associated with female foraging as weighted by the proportion of hatchlings that emerge from their respective nests.
We created loggerhead-specific δ13C and δ15N isoscapes (Supplementary Fig. S1) and used a bivariate normal model to assign a probability of origin to each raster cell for every individual female turtle in the dataset. The median of the normalized posterior probabilities for raster cells associated with known latitude-longitude coordinates of known-origin turtles (calibration dataset) was 0.92; the value of the first quartile of modeled probability values for known locations was 0.78 (Supplementary Fig. S2). We modeled an evidence-based index of foraging area importance for the entire dataset of unknown females (n = 749) as well as for the subset of females for which we had nest fate information (n = 513 females) (Supplementary Table S3). The resulting maps of the relative importance of foraging geographies (foraging indices) were similar for the two data sets; here, we present only the results for the latter subset (n = 513 females) that includes the reproductive data.
This approach allowed the assignment of all individuals in the unknown dataset and the compilation of overall and annual population-level summaries (Figs 1 & 2). Seven foraging hotspots were consistently identified by the modeled foraging index for loggerheads nesting at the ACNWR (Fig. 1). These consist of the waters: (i) centered around the Delmarva Peninsula (N Hatteras); (ii) along the continental shelf next to North Carolina (S Hatteras); (iii) adjacent to the South Carolina/Georgia border (SC-GA); (iv) adjacent to east central Florida (E FL); (v) on the continental shelf south of Andros in the Great Bahama Bank (Bahamas); (vi) near the distal portion of the Florida Keys (FL Keys), and (vii) along the continental shelf from the west coast of Florida centered around Tampa Bay and Charlotte Harbor (W FL).
We found conspicuous inter-annual variability in the relative values of the foraging area indices for the ACNWR nesting aggregation (Fig. 2). Some foraging hotspots were synchronous (i.e. appeared to contribute similar proportions of nesters in a given year) while others exhibited the opposite pattern (Fig. 3a). The southern hotspots (Bahamas and Florida Keys) contributed similarly in each given year (high contributions in 2007 and 2014; low in 2009 and 2012). We found similar synchronous patterns for northern (North and South Hatteras) areas. Pulses of contributions from northern foraging areas (in 2009 and 2012) corresponded to a drop in apparent use of southern hotspots and vice versa. When the relative contribution values of southern foraging areas were highest (2007 and 2014), northern hotspot index values were at their lowest. The comparative apparent use across the seven foraging hotspots was similar for the five remaining years (2008, 2010, 2011, 2013 and 2015). Lastly, the relative contributions of the foraging hotspot adjacent to the nesting beach (east central Florida) appeared consistently high and fairly stable over time (mean = 0.31, range: 0.27–42), indicating regular use by a large portion of females nesting at this critically important site. The overall population-level hypothesis test for no difference in the proportional distribution of use by nesting females across the seven hotspots, pooled over all nine years, suggested that the proportional use was not uniform (Friedman Χ 2 (6) = 18.668, P = 0.005; Fig. 1 & Fig. 3b). Post-hoc pair-wise null hypothesis tests for the same uniformity, and examination of the data shown in Fig. 3a,b suggested that the east central Florida foraging area was used by more nesting females than all other foraging areas except for North Hatteras.
Examining the overall patterns, we found agreement among average relative importance of foraging areas to the nesting aggregation based on nesting females (Fig. 1), egg and emergent numbers (Supplementary Fig. S4). Foraging areas used by large numbers of breeding females provided nutrients and energy for high egg production and in turn yielded high numbers of viable offspring. Examination of the data and results from the hypothesis test for no difference in the proportional distribution of rate of emergence associated with female foraging areas both suggested that the distribution of emergent production was likewise not uniform (Fig. 3d, Fig. 4; Χ 2 (6) = 22.762, P = 0.001); however, the patterns of deviation from uniformity differed from those for the mean number of nesting females. Nests laid by females that used the northernmost foraging hotspot (North Hatteras) had lower emergence success than females foraging at lower-latitudes (Bahamas, Florida Keys and West Florida; Fig. 3d). Overall, females foraging in the Bahamas and Florida Keys laid nests with higher mean annual emergence success rates (Fig. 4). There was notable geographic patterning in relative importance of foraging areas to emergence success within and among years. Overall emergence success was relatively high in some years (2012–2015), intermediate in others (2007–2008, 2010–2011) and low in 2009, regardless of the foraging area females used prior to each nesting season (Fig. 3c & Fig. 5). Within-year differences in emergence success among foraging hotspots were comparatively low. Nevertheless, our results indicated that females foraging in the southern hotspots (the Bahamas and FL Keys) showed consistently higher emergence success than the other hotspots for all but one year (2010) (Fig. 3c).
The results of this study are particularly relevant from a conservation standpoint because it focuses on the major nesting aggregation in the Atlantic and determined likely geographic origin for a large number of truly unknown loggerheads (n = 749) over nine years (2007–2015). The continuous-surface approach allowed the inclusion of all encountered individuals, improving previous assignment models to origin in sea turtles13,14,20,21,22. The probabilistic assignment to origin with isoscapes has been used in terrestrial systems to track dispersal and aggregate individual results to identify geographic hotspots at the population level31,32,33,34. Though this method has been validated in few marine systems24,30, it has not been previously implemented to infer origin of unknown individuals.
The geographic locations of the seven foraging hotspots identified by the model agreed with available telemetry data14,27,28 and flipper tag returns29,35, while providing novel information on their relative contributions (within and among years) to the ACNWR nesting aggregation. Our findings based on a more representative sample of this rookery (i.e., dozens of individual females sampled annually across the entire nesting season) showed that the continental shelf off east central Florida consistently contributed the most nesting females to the ACNWR. Females residing year-round in east central Florida have access to moderately high productive waters36 and incur low energetic costs associated with migration allowing them to invest more resources in reproduction, thereby increasing overall reproductive success. However, the importance of east central Florida as a year-round foraging hotspot has been underestimated by satellite telemetry studies involving post-nesting loggerheads (11%, n = 6 of 56 females)14,27,28,37. Evidence supporting a greater importance of the middle and outer continental shelf off east central Florida as a year-round foraging hotspot for adult loggerheads is based on a satellite telemetry study of adult male loggerheads (33%, n = 8 of 24 individuals)38 and to some extent on long-term stranding records (FWC unpublished data) and aerial surveys39. The low percentage of satellite-tracked nesting females reported to reside in this area may be an artefact of small telemetry sample sizes in a given year (4 females tracked/year on average) or time of deployment. Telemetry studies conducted at the ACNWR aimed to identify female post-nesting migration destinations; thus, satellite tag deployment was temporally biased toward the end of the nesting season (end of July and August). Turtles migrating from distinct foraging areas may differ in their nesting phenologies (i.e., time of arrival and departure from the nesting area); hence, the combination of a small sample size and temporally biased sampling may be responsible for underestimating the importance of east central Florida for this rookery. Previous work relying on SIA to infer foraging areas used by loggerheads nesting at the ACNWR produced conflicting results on the importance of east central Florida as a foraging hotspot despite sharing common methodology (nominal approach, e.g., Discriminant Function Analysis) with the only difference being the number of isotopically distinct foraging areas of origin used in the assignment model (3 vs. 4)13,14,22. Here, the continuous-surface approach overcame limitations of previous sea turtle isotopic research: boundary definition of possible source of origin, low spatial resolution, and inability to assign all individuals with adequate accuracy.
We found considerable inter-annual variability in relative importance of foraging areas to the nesting aggregation suggesting plasticity in migratory connectivity linkages between foraging areas and the nesting site. Some years showed weak connectivity (i.e., all foraging areas contributed similarly as in 2013), while others were characterized by relatively strong connectivity (i.e., pulses of females coming either from the northern or the southern hotspots as in 2012 and 2014, respectively). The opposite pulse observed in some of the years suggests that females experience different environmental conditions at the two latitudinal extremes. Moreover, hotspots geographically close to each other (the Florida Keys and the Bahamas; North and South Hatteras) tended to act in synchrony. These similarities are likely the consequence of geographic proximity and shared marine ecoregions36. Females undertake breeding migration every 1 to 9+ years6 but most individuals return to their natal beach every two or three years40,41. The reverse pattern in some years (e.g. 2012 vs. 2014) indicated that many females were on a similar breeding schedule on those years. However, over the nine-year survey there were no clear patterns of periodicity of contributions from different foraging areas to the rookery suggesting variability in remigration interval (the number of years between successive nesting seasons for a particular individual) among females. The complexity in the migratory linkages we observed could be related to inter-annual environmental variability at the turtle’s foraging areas which is known to affect remigration intervals42,43,44. Models linking climatic variables and remigration intervals have not been developed for loggerheads nesting in the NWA, even though the NWA hosts the largest nesting population in the world for this species7. Understanding mechanistic links between climate and reproductive ecology will aid interpretation of trends in annual nest counts, which are the metric used to determine population status and set recovery goals (e.g., IUCN Red List Assessments, NMFS & USFWS recovery plans).
The relative importance of individual hotspots varied from year to year over the nine-year study. This result differs from previous isotopic and telemetry studies that found strong connectivity for NWA loggerhead females but were based on fewer years or small sample sizes of satellite tags deployed in any given year13,20,22,28,45. Our results suggest that overall the aggregation of females nesting at the ACNWR has relatively weak migratory connectivity, which could confer some level of resilience in light of climate change and other stochastic or anthropogenic threats. However, nine years represent only a short period of time for this long-living species—a fraction of a loggerhead generation. We emphasize the importance of conducting long-term studies to understand sea turtle migratory connectivity and reproductive ecology because nest counts fluctuate widely and females have variable remigration intervals; thus, decades are required to capture long-term trends.
NW Atlantic loggerheads undertake ocean-wide developmental migrations during their life cycle that can complicate conservation efforts46. The identification of adult foraging hotspots and understanding foraging area dynamics are critical to the development of effective conservation measures. The continuous-surface approach model identified the waters in the Great Bahama Bank (south of Andros and North of Cuba) as the only important foraging hotspot for the ACNWR rookery outside the USA Economic Exclusive Zone (EEZ), potentially simplifying strategies for the conservation of this critically important nesting aggregation. Telemetry as well as previous isotopic work revealed that the Great Bahama Bank is also an important foraging residence area for adult females from other genetically distinct sub-units within the NWA loggerhead subpopulation20,22,24,45,47,48. Yet, to our knowledge no research has been directly conducted on this important loggerhead foraging aggregation. Commercial fishing takes place on the continental shelves of the Bahamas targeting mostly spiny lobsters, snappers and conch49. Loggerheads mostly forage on these benthic invertebrates; hence, the Bahamas fishery could affect this loggerhead population both directly (e.g., causing mortality due to entanglement in fishing gears) and indirectly (e.g., by decreasing food availability). Harvesting sea turtles has been illegal in the Bahamas since 2009, but law enforcement is limited due to the vast marine area to patrol48. Our data identify the Great Bahama Bank south of Andros as a hotspot for adult loggerheads; we encourage the development of in-water capture programs to characterize this foraging aggregation.
The seven foraging hotspots identified in this study supported large numbers of breeding females thereby providing nutrients and energy for a large number of eggs and hatchlings. Assuming that our sampling of single nesting events were representative for a turtle that is expected to produce multiple clutches over a nesting season, the population-level summaries indicated that reproductive success differed among hotspots. Southern foraging areas yielded higher emergence success. In contrast, nests laid by northern foraging females yielded proportionately fewer emergents resulting in more net inflow of energy and allochthonous nutrients to the oligotrophic beach ecosystem50,51. Prior telemetry showed that most NWA loggerheads exhibit three main foraging strategies (seasonal-large scale, seasonal small-scale and a year-round). Females using the northernmost foraging hotspot (North Hatteras) undertake seasonal shelf-constrained movements between summer and winter areas14,45, loggerheads foraging in the South Atlantic Bight, where three of the hotspots we identified are located (South Hatteras, South Carolina-Georgia border and east central Florida), move short distances along the western edge of the Gulf Stream45, while females using the southernmost areas (Bahamas and Florida Keys) reside there year-round. Hence, northern foraging females incur higher energetic cost of migration compared to the other groups and the lower reproductive success of their nests perhaps may be related to differential allocation of energy within the reproductive component (i.e., migration vs. egg development cost). Although, egg quality was shown not to vary among females using different foraging areas and nesting in Japan52, the relationships between egg quality, foraging area location and energetic cost of migration have not been investigated for NWA loggerheads. On the other hand, previous isotopic work found that loggerheads foraging near large coastal estuaries at high latitudes have δ15N values higher than expected that may be associated with agricultural runoff and anthropogenic waste23. We hypothesize differences in egg loss and, thus, nutrient transfer among foraging areas may be a result of differential exposure to contaminants such as persistent organic pollutants (POPs), often used in agriculture, that could lead to reduced emergence success. While egg quality does not seem to vary among females using different foraging areas52, maternal transfer of POPs has been documented in sea turtles53 and POPs have been shown to affect embryonic mortality54,55. Thus, if POP concentrations differ among hotspots and females foraging in northern areas are exposed to higher concentrations, their eggs will likely have a lower survival. To our knowledge, no study has measured contaminant concentration in satellite tagged post-nesting females, although Alava et al.56 provided indirect support to our hypothesis, and differences in POP exposure among loggerheads using geographically distinct foraging areas were determined in adult male loggerheads in the NWA57.
We found considerable inter-annual variability in relative importance of foraging areas to emergence success. Regardless of the foraging area, there were relatively high years of emergence success (2012–2015) and 2009 was unusually low. Several studies have demonstrated that hatchling productivity (egg development and hatchling emergence) is affected by prevailing local climatic conditions (e.g. precipitation regimes and hurricane events), variations in nest microclimate and predation58,59,60,61. We attribute the 2009 overall low emergence success to the unusually high raccoon (Procyon lotor) predation rate documented in the ACNWR in that year (n = 21 out of 169, 12% of the nests included in the nest productivity assessment, FWC unpublished data) compared to the other years of the study (average 5%, SD ± 4%). In addition, previous isotopic studies found no differences in reproductive success among females utilizing different foraging areas13,20, and no differences in egg size and nutritional components were found between oceanic and neritic foraging loggerheads in the Pacific Ocean52. Although within-year differences in emergence success associated with different hotspots were generally low, emergence success was consistently slightly higher for nests laid by females foraging in southern areas for all the years of the study but 2010. We hypothesize that loggerheads that feed in the Bahamas and Florida Keys may have greater prey availability of higher nutritionally quality and/or be exposed to lower concentrations of contaminants which could result in higher emergence success.
Using isoscapes, we were able to derive population-level information to gain a better understanding of migratory connectivity for a critically important loggerhead nesting aggregation and inform managers on where to focus efforts to maximize conservation output. Specifically, our study identified two areas that should be prioritized for future research and conservation efforts: (i) the middle and outer continental shelf in east central Florida, a previously overlooked area and (ii) the continental shelf south of Andros in the Great Bahama Bank. The latter is the only major hotspot we identified outside the US EEZ and also appears to yield higher numbers of emerging hatchlings. The importance of these two hotspots as year-round foraging areas for loggerheads should be further investigated using tools such as aerial surveys, visual transects and in-water captures, increased telemetry effort, and interviews with commercial and recreational fishermen outside of the breeding season. A representative isotopic sample of the annual nesting population could be used in the future to (1) interpret trends in abundance at nesting beaches and demographic parameters affecting those trends and (2) monitor foraging aggregations trends from nesting beaches. We emphasize the importance of a long-term and intensive sampling for stable isotope analysis on nesting beaches combined with periodic telemetry studies to evaluate temporal isotopic consistency and prevent erroneous conclusions. Ultimately, the ACNWR is a good indicator rookery for monitoring the relative health and trends of the NWA loggerhead subpopulation because this 21+ km stretch of beach hosts 14.7% of the mean annual Florida loggerhead nest totals, yet its length represents only 1.6% of the surveyed beaches (FWC/FWRI Statewide Nesting Beach Survey Program database as of 20 February 2016). Hence, a better understanding of the movements and origins of loggerheads nesting at ACNWR may allow managers to identify potential areas of interaction with anthropogenic activities such as those associated with fishery operations and oil exploration. This study represents the first implementation of probabilistic assignment of origin with unknown individuals of a highly migratory marine species. Even though we used loggerhead-specific isoscapes, similar methodology could be applied to other migratory species.
This study was performed in accordance with the guidelines of the University of Central Florida Institutional Animal Care and Use Committee (IACUC) and the Florida Fish and Wildlife Conservation Commission. The animal use protocol for this research was reviewed and approved by the University of Central Florida Institutional Animal Care and Use Committee (IACUC protocols #09–22 W, #12–22 W, #13–22 W, #15–13 W). Procedures were approved under the Florida Fish and Wildlife Conservation Commission (Marine Turtle Permit #25, #186 and #200).
This study was conducted on the Brevard County portion (21+ km) of the ACNWR (27.917° N, 80.483°), a critically important loggerhead nesting beach in east central Florida. Here, all nesting activity has been continually monitored since 1982, and a subsample of females is encountered and tagged using both Inconel flipper tags and passive integrated transponders during annual nighttime surveys41.
Female data, sample collection, and stable isotope preparation
A total of 749 loggerhead females were sampled for SIA (Supplementary Table S3). To avoid pseudoreplication, each turtle was tagged with Inconel flipper tags and, starting in 2009, with passive integrated transponders; thus, each female is represented only once in the dataset. Nighttime tagging effort was constant and sampling for this study spanned the nesting seasons (May–August) and the 21 km of ACNWR beach from 2007 to 2015. A subset (n = 513) of nests laid at the time of sampling were left in situ and marked for post-hatching nest content evaluation62 (Table 1). Tissues (skin and blood from nesting females, and contents of unhatched eggs from females tagged at night) were collected following methods described in a previous study13. These tissues have known isotopic relationships13,15 and are assumed to represent the isotopic signature of foraging areas used during the non-breeding season12,14.
Samples were prepared for isotopic analysis following standard procedures13,15. Prepared samples were sent for mass spectrometry analysis to the University of South Florida, College of Marine Science. Replicate measurements of internal lab reference materials (1577b Bovine liver) were used to estimate analytical precision and yield a precision (reflecting ± 1 SD) of ±0.16‰ for δ13C and 0.17‰ for δ15N. All tissue isotopic values were converted to a common currency (epidermis) using established regression equations13,15. Epidermis samples were available for 543 females. Epidermis isotopic values were derived from unhatched egg and red blood cell values for 156 and 50 females, respectively.
Clutch sizes were determined either within 12 hours of deposition or at time of post-hatching excavation. The number of hatchlings that emerged from an individual nest (hereafter, “emergents”) was determined at the time of post-hatching excavation and was calculated as: # of hatched eggs − (dead hatchlings found in nest + live hatchlings found in nest). We followed established protocols used to evaluate nests post-hatching62. We included all 513 nests in the assessment of hatchling production, including those that were disturbed by storm-induced erosion or predators if the initial clutch size was recorded at the time of deposition. By doing so, we provide an unbiased representation of the female investment in the specific nesting event (expressed as clutch size) and reproductive output (indicated by the number of hatchlings that emerged). Loggerheads lay several clutches63 during a nesting season and the high number of nests at the ACNWR (12,350 nests/year, 5-year average from 2011 to 2015) prevented us from identifying and following the fate of all the nests laid by individual females. Thus, we did not investigate the investment of individual females during the entire nesting season but used the nest deposited the night of sampling as a proxy for that year female’s reproductive output. We then modeled expected number of eggs and emergents to explore annual variation in egg and hatchling production associated with geographic foraging hotspots.
Computation of raster cell probabilities of use by individual loggerheads
We updated and re-analyzed the dataset comprised of 205 known-origin loggerheads23 that were sampled for SIA. An additional 22 females13 were equipped with satellite tags after nesting on Florida beaches, sampled for SIA, and augmented the known foraging areas used by loggerheads nesting at the ACNWR. This updated dataset (n = 227) was used for calibration. The isotopic values of these known-location loggerheads were used to develop carbon and nitrogen loggerhead-specific isoscapes (Supplementary Fig. S1) based on the empirical Bayesian kriging interpolation EBK64; routine available in ArcGIS 10.2 (Esri Redlands, CA) following previously developed procedures23. We used the resulting δ13C and δ15N isoscapes and assumed a bivariate normal distribution for the error term in the isotope model for assigning probability of foraging area origin. We parameterized this distribution independently for each raster cell in the study area. We used the predicted δ13C and δ15N from the EBK as the vector of means, and we estimated the variance-covariance matrix for δ13C and δ15N by combining information on tissue δ13C and δ15N from loggerheads that could be linked to known foraging areas from satellite data and in-water captures (sampling-based variances) and the rasters for the kriging errors (model-based variances). Specifically, we estimated the variance-covariance matrix for δ13C and δ15N from tissue samples at each of the six broad foraging areas identified from satellite data and in-water captures13,23: Canada (CAN), Mid-Atlantic Bight (MAB), South Atlantic Bight (SAB), Subtropical Northwest Atlantic (SNWA), Florida Keys (FL Keys) and Southwest Florida (SWFL). From these foraging-area specific matrices, we computed the average among-turtle correlations and variances, which were in turn combined with the kriging model variances and covariances for each raster cell. ArcGIS produced a raster of standard errors from the kriging model described above. We squared these values to approximate variances and added them to the mean sample-based variances for δ13C and δ15N for each cell. That is, each raster cell was given the same value for the turtle tissue-based δ13C and δ15N variance, but could have a unique variance from the kriging model. By summing these variances, we implicitly assume independence between the variance-generating process for observed δ13C and δ15N in tissues from a given foraging area and for the kriging model; we have no reason to believe that the foraging behavior of loggerheads would influence the way in which values are spatially interpolated in the kriging model. Because each raster cell had only one modeled value for δ13C and one for δ15N, and the modeling algorithm provided estimates only for the univariate standard errors (and not the bivariate covariances), we used the tissue-based estimates of covariance for the off-diagonals in the variance-covariance matrix.
We followed Wunder (2010) to create a spatially-explicit posterior probability distribution for each individual turtle in both the calibration (n = 227) and the assignment (n = 749) datasets. More specifically, we used the predicted values from the kriging model as the means and the variance-covariance matrix described above and estimated the posterior probability density function that each raster cell represented the foraging site origin from the measured tissue values for each turtle. All cells in each individual turtle raster were then normalized by the maximum value in that raster, creating a spatially-explicit distribution of cell values ranging from 0 to 1. This process resulted in an assignment surface for each individual turtle where a value of 1 represents the most probable foraging location and 0 the least probable25.
We summed the rescaled assignment surfaces for the 749 turtles in the assignment dataset (unknown foraging area) by year to identify the comparative strength of evidence for foraging regions across the study period. The resultant sums do not indicate the number of turtles that foraged at each given cell. The kriging models produced rasters with the same predicted values for δ13C and δ15N at more than one cell. Because we used the kriging predictions for each cell as the expected value for the cell in the assignment step, the assignment models also produced rasters where more than one cell was given the same assignment probability. Thus, when the rasters were rescaled to the maximum assignment value, more than one cell was given a value of 1. For this reason, the summed rasters should not be interpreted directly as the number of turtles foraging at each cell, but rather as the probable number of turtles that used the cell. These sums can be thought of as a probability-weighted index of the strength of evidence that a raster cell was the source of δ13C and δ15N values observed in the turtle tissues sampled each year (i.e., an index of foraging importance).
To identify the spatial origins of organic material for reproduction, we weighted the rescaled assignment rasters for an individual turtle using the known clutch size (number of eggs) and the estimated number of emergents from the nest for that turtle. That is, we computed the product of the number of eggs (or emergents) and the rescaled assignment probability value for every cell in the raster for each individual turtle. These rasters were then likewise summed by year to evaluate spatial patterns over time. These results can be informally considered as indices of the probable spatial distribution of contributions to reproduction (eggs or emergents) in the population (i.e., indices of reproductive importance). Hypothesis testing for no difference in mean numbers of nesting adults and emergence rate among identified hotspots for foraging and reproductive importance over the nine-year period was done using the Friedman rank sum test. Post-hoc hypothesis tests for pairwise similarity in mean numbers of nesting adults and emergence rate between hotspots were done using Conover tests adjusted with the Benjamini-Hochberg False Discovery Rate (FDR) method65.
All maps were newly created for this study using ArcGIS v. 10.2 (Esri Redlands, CA). We used R66,67 for all analyses, including estimating and applying all components of the assignment models, and the null hypothesis testing.
The dataset analyzed in this study and the R scripts used to create the probability maps included in this published article are available as Supplementary Information files (Supplementary Data S3 and Supplementary Note S5).
Costa, D. P., Breed, G. A. & Robinson, P. W. New insights into pelagic migrations: implications for ecology and conservation. Annual Review of Ecology, Evolution, and Systematics 43, 73–96 (2012).
Webster, M. S., Marra, P. P., Haig, S. M., Bensch, S. & Holmes, R. T. Links between worlds: unraveling migratory connectivity. Trends Ecol. Evol. 17, 76–83 (2002).
Hobson, K. A. & Norris, D. R. Animal migration: a context for using new techniques and approaches. Terrestrial Ecology 2, 1–19 (2008).
Rundel, C. W. et al. Novel statistical methods for integrating genetic and stable isotope data to infer individual‐level migratory connectivity. Mol. Ecol. 22, 4163–4176 (2013).
Rees, A. et al. Are we working towards global research priorities for management and conservation of sea turtles? Endang. Species Res. 31, 337–382 (2016).
Miller, J. D. In The Biology of Sea Turtles (eds P. L. Lutz & J. A. Musick) 51–81 (CRC Marine Science Series, CRC Press, Inc., 1997).
Casale, P. & Tucker, A. D. Caretta caretta. IUCN Red List of Threatened Species. Version 2016.2. www.iucnredlist.org . Downloaded on 23 September 2016. (2015).
National Marine Fisheries Service and United States Fish and Wildlife Service. Recovery plan for the northwest Atlantic population of the loggerhead sea turtle (Caretta caretta), Second Revision., 323 pp. (National Marine Fisheries Service, Silver Spring, MD, 2008).
Esteban, N., Mortimer, J. A. & Hays, G. C. In Proc. R. Soc. B. 20162581 (The Royal Society).
National Research Council. Assessment of Sea-Turtle Status and Trends: Integrating Demography and Abundance. (The National Academies Press, 2010).
Godley, B. J. et al. Satellite tracking of sea turtles: Where have we been and where do we go next? Endang. Species Res. 4, 3–22, https://doi.org/10.3354/esr00060 (2008).
Hatase, H. et al. Size-related differences in feeding habitat use of adult female loggerhead turtles Caretta caretta around Japan determined by stable isotope analyses and satellite telemetry. Mar. Ecol.-Prog. Ser. 233, 273–281 (2002).
Ceriani, S. A. et al. Carry-over effects and foraging ground dynamics of a major loggerhead breeding aggregation. Mar. Biol. 162, 1955–1968, https://doi.org/10.1007/s00227-015-2721-x (2015).
Ceriani, S. A., Roth, J. D., Evans, D. R., Weishampel, J. F. & Ehrhart, L. M. Inferring Foraging Areas of Nesting Loggerhead Turtles Using Satellite Telemetry and Stable Isotopes. PLoS ONE 7, doi:https://doi.org/10.1029/2005GB002456 (2012).
Ceriani, S. A., Roth, J. D., Ehrhart, L. M., Quintana-Ascencio, P. F. & Weishampel, J. F. Developing a common currency for stable isotope analyses of nesting marine turtles. Mar. Biol., 257–2268 (2014).
Vander Zanden, H. B., Bjorndal, K. A., Reich, K. J. & Bolten, A. B. Individual specialists in a generalist population: results from a long-term stable isotope series. Biol. Lett. (2010).
Rees, A. et al. Are we working towards global research priorities for management and conservation of sea turtles? (2016).
Broderick, A. C., Coyne, M. S., Fuller, W. J., Glen, F. & Godley, B. J. Fidelity and over-wintering of sea turtles. Proc. R. Soc. B-Biol. Sci. 274, 1533–1538, https://doi.org/10.1098/rspb.2007.0211 (2007).
Hatase, H., Omuta, K. & Tsukamoto, K. A mechanism that maintains alternative life histories in a loggerhead sea turtle population. Ecology 94, 2583–2594 (2013).
Vander Zanden, H. B. et al. Foraging areas differentially affect reproductive output and interpretation of trends in abundance of loggerhead turtles. Mar. Biol. 161, 585–598 (2014).
Eder, E. et al. Foraging dichotomy in loggerhead sea turtles Caretta caretta off northwestern Africa. Mar. Ecol. Prog. Ser. 470, 113–122 (2012).
Pajuelo, M. et al. Assignment of nesting loggerhead turtles to their foraging areas in the Northwest Atlantic using stable isotopes. Ecosphere 3, art89, https://doi.org/10.1890/es12-00220.1 (2012).
Ceriani, S. A. et al. Modeling and mapping isotopic patterns in the Northwest Atlantic derived from loggerhead sea turtles. Ecosphere 5, doi:https://doi.org/10.1890/es14-00230.1 (2014).
Vander Zanden, H. B. et al. Determining origin in a migratory marine vertebrate: a novel method to integrate stable isotopes and satellite tracking. Ecol. Appl. 25, 320–335 (2015).
Wunder, M. B. Using Isoscapes to Model Probability Surfaces for Determining Geographic Origins. 251–270, doi:https://doi.org/10.1007/978-90-481-3354-3_12 (2010).
Ceriani, S. A. & Meylan, A. B. Caretta caretta (North West Atlantic subpopulation). The IUCN Red List of Threatened Species 2015: e.T84131194A84131608. http://dx.doi.org/10.2305/IUCN.UK.2015-4.RLTS.T84131194A84131608.en. Downloaded on23 December 2016., (2015).
Dodd, C. K. & Byles, R. Jr. Post-nesting movements and behavior of loggerhead sea turtles (Caretta caretta) departing from east-central Florida nesting beaches. Chelonian Conserv. Biol. 4, 530–536 (2003).
Foley, A. M. et al. Postnesting migratory behavior of loggerhead sea turtles Caretta caretta from three Florida rookeries. Endang. Species Res. 21, 129–142, https://doi.org/10.3354/esr00512 (2013).
Meylan, A. B., Bjorndal, K. A. & Turner, B. J. in Biol. Conserv. 26, 79–90 (1983).
Trueman, C. N., MacKenzie, K. M. & St John Glew, K. Stable isotope-based location in a shelf sea setting: accuracy and precision are comparable to light-based location methods. Methods Ecol. Evol., n/a–n/a, doi:https://doi.org/10.1111/2041-210X.12651 (2016).
Hobson, K. A., Wunder, M. B., Van Wilgenburg, S. L., Clark, R. G. & Wassenaar, L. I. A method for investigating population declines of migratory birds using stable isotopes: origins of harvested lesser scaup in North America. PLoS One 4, e7915, https://doi.org/10.1371/journal.pone.0007915 (2009).
Flockhart, D. T. et al. Tracking multi-generational colonization of the breeding grounds by monarch butterflies in eastern North America. Proc Biol Sci 280, 20131087, https://doi.org/10.1098/rspb.2013.1087 (2013).
Van Wilgenburg, S. L. & Hobson, K. A. Combining stable-isotope (δD) and band recovery data to improve probabilistic assignment of migratory birds to origin. Ecol. Appl. 21, 1340–1351 (2011).
Haché, S., Hobson, K. A., Bayne, E. M., Van Wilgenburg, S. L. & Villard, M.-A. Tracking natal dispersal in a coastal population of a migratory songbird using feather stable isotope (δ2H, δ34S) tracers. PloS one 9, e94437 (2014).
Moncada, F. et al. Movement patterns of loggerhead turtles Caretta caretta in Cuban waters inferred from flipper tag recaptures. Endang. Species Res. 11, 61–68, https://doi.org/10.3354/esr00248 (2010).
Wilkinson, T. A. et al. Marine Ecoregions of North America. (Instituto Nacional de Ecología, 2009).
Evans, D. R. Sea turtle tracking: tracking loggerheads from the Archie Carr Refuge. https://conserveturtles.org/sea-turtle-tracking-tracking-loggerheads-archie-carr-refuge/. (2015).
Arendt, M. D. et al. Distributional patterns of adult male loggerhead sea turtles (Caretta caretta) in the vicinity of Cape Canaveral, Florida, USA during and after a major annual breeding aggregation. Mar. Biol. 159, 101–112, https://doi.org/10.1007/s00227-011-1793-5 (2011).
Turtle Expert Working Group. An assessment of the loggerhead turtle population in the western North Atlantic Ocean. NOAA Technical Memorandum NMFS-SEFSC 575, 131 (2009).
Richards, P. M. et al. Sea turtle population estimates incorporating uncertainty: a new approach applied to western North Atlantic loggerheads Caretta caretta. Endang. Species Res. 15, 151–158, https://doi.org/10.3354/esr00379 (2011).
Ehrhart, L., Redfoot, W., Bagley, D. & Mansfield, K. Long-term trends in loggerhead (Caretta caretta) nesting and reproductive success at an important western Atlantic rookery. Chelonian Conserv. Biol. 13, 173–181 (2014).
Solow, A. R., Bjorndal, K. A. & Bolten, A. B. Annual variation in nesting numbers of marine turtles: the effect of sea surface temperature on re-migration intervals. Ecol. Lett. 5, 742–746 (2002).
Saba, V. S. et al. The effect of the El Nino Southern Oscillation on the reproductive frequency of eastern Pacific leatherback turtles. J. Appl. Ecol. 44, 395–404, https://doi.org/10.1111/j.1365-2664.2007.01276.x (2007).
Chaloupka, M., Kamezaki, N. & Limpus, C. Is climate change affecting the population dynamics of the endangered Pacific loggerhead sea turtle? J. Exp. Mar. Biol. Ecol. 356, 136–143, https://doi.org/10.1016/j.jembe.2007.12.009 (2008).
Griffin, D. B. et al. Foraging habitats and migration corridors utilized by a recovering subpopulation of adult female loggerhead sea turtles: Implications for conservation. Mar. Biol. 160, 3071–3086, https://doi.org/10.1007/s00227-013-2296-3 (2013).
Mansfield, K. L. & Putman, N. F. Oceanic habits and habitats. Biology of sea turtles 3, 189–211 (2013).
Girard, C., Tucker, A. D. & Calmettes, B. Post-nesting migrations of loggerhead sea turtles in the Gulf of Mexico: dispersal in highly dynamic conditions. Mar. Biol. 156, 1827–1839, https://doi.org/10.1007/s00227-009-1216-z (2009).
Hart, K. M., Sartain, A. R. & Fujisaki, I. Bahamas connection: residence areas selected by breeding female loggerheads tagged in Dry Tortugas National Park, USA. Animal Biotelemetry 3, 3, https://doi.org/10.1186/s40317-014-0019-2 (2015).
FAO. Fishery and Aquaculture Country Profiles. Bahamas (2009). Country Profile Fact Sheets. In: FAO Fisheries and Aquaculture Department [online]. Rome. Updated 1 May 2009. [Cited 23 December 2016]. http://www.fao.org/fishery/facp/BHS/en, (2009).
Bouchard, S. S. & Bjorndal, K. A. Sea turtles as biological transporters of nutrients and energy from marine to terrestrial ecosystems. Ecology 81, 2305–2313 (2000).
Hannan, L. B., Roth, J. D., Ehrhart, L. M. & Weishampel, J. F. Dune vegetation fertilization by nesting sea turtles. Ecology 88, 1053–1058 (2007).
Hatase, H., Omuta, K. & Komatsu, T. Do loggerhead turtle (Caretta caretta) eggs vary with alternative foraging tactics? J. Exp. Mar. Biol. Ecol. 455, 56–61 (2014).
Stewart, K. R., Keller, J. M., Templeton, R., Kucklick, J. R. & Johnson, C. Monitoring persistent organic pollutants in leatherback turtles (Dermochelys coriacea) confirms maternal transfer. Mar. Pollut. Bull. 62, 1396–1409, https://doi.org/10.1016/j.marpolbul.2011.04.042 (2011).
Perrault, J., Wyneken, J., Thompson, L. J., Johnson, C. & Miller, D. L. Why are hatching and emergence success low? Mercury and selenium concentrations in nesting leatherback sea turtles (Dermochelys coriacea) and their young in Florida. Mar. Pollut. Bull. 62, 1671–1682, https://doi.org/10.1016/j.marpolbul.2011.06.009 (2011).
Van de Merwe, J. P., Hodge, M., Whittier, J. M., Ibrahim, K. & Lee, S. Y. Persistent organic pollutants in the green sea turtle Chelonia mydas: nesting population variation, maternal transfer, and effects on development. Mar. Ecol.-Prog. Ser. 403, 269–278, https://doi.org/10.3354/meps08462 (2010).
Alava, J. J. et al. Geographical variation of persistent organic pollutants in eggs of threatened loggerhead sea turtles (Caretta caretta) from Southeastern United States. Environ. Toxicol. Chem. 30, 1677–1688, https://doi.org/10.1002/etc.553 (2011).
Ragland, J. M., Arendt, M. D., Kucklick, J. R. & Keller, J. M. Persistent organic pollutants in blood plasma of satellite-tracked adult male loggerhead sea turtles (Caretta caretta). Environ. Toxicol. Chem. 30, 1549–1556, https://doi.org/10.1002/etc.540 (2011).
Miller, J. D., Limpus, C. J. & Godfrey, M. H. in Bolten, A. B.,Witherington, B. E. Eds., Loggerhead Sea Turtles. Smithsonian Books, Washington, D.C. 319 pp.; 2003, p. 125–143 (2003).
Pike, D. A. & Stiner, J. C. Sea turtle species vary in their susceptibility to tropical cyclones. Oecologia 153, 471–478 (2007).
Tomillo, P. S. et al. Global analysis of the effect of local climate on the hatchling output of leatherback turtles. Scientific reports 5, 16789 (2015).
Tomillo, P. S. et al. Climate driven egg and hatchling mortality threatens survival of Eastern Pacific leatherback turtles. PLoS One 7, e37602 (2012).
Brost, B. et al. Sea turtle hatchling production from Florida (USA) beaches, 2002-2012, with recommendations for analyzing hatching success. Endang. Species Res. 27, 53–68, https://doi.org/10.3354/esr00653 (2015).
Tucker, A. D. Nest site fidelity and clutch frequency of loggerhead turtles are better elucidated by satellite telemetry than by nocturnal tagging efforts: implications for stock estimation. J. Exp. Mar. Biol. Ecol. 383, 48–55 (2010).
Pilz, J. & Spöck, G. Why do we need and how should we implement Bayesian kriging methods. Stochastic Environmental Research and Risk Assessment 22, 621–632 (2008).
Benjamini, Y. & Hochberg, Y. Controlling the false discovery rate: a practical and powerful approach to multiple testing. J. R. Stat. Soc. Series B 57, 289–300 (1995).
R Development Core Team. R: A language and environment for statistical computing. (R Foundation for Statistical Computing, 2016).
Pohlert, T. The pairwise multiple comparison of mean ranks package (PMCMR). R package, http://CRAN.R-project.org/package=PMCMR (2014).
We thank B. Sharma, R. Woods, A. Hays, A. Sterner, C. Sanchez, C. Long, F. Gusmao, R. Chabot, C. Amato, K. Cope, T. Williamson, M. Balfour, J. Elliott, K. Phillips, G. Stahelin, D. Bagley, and forty undergraduate students for their help with sample collection at the ACNWR and assistance with lab work. We thank the ACNWR Managers and in particular K. Kneifl for supporting our research. Additional thanks to G. Worthy for providing laboratory access and E. Goddard for assistance with stable isotope analysis. This work was supported by several grants awarded from the Sea Turtle Grants Program (09-055R, 10-023R, 11-021R, 12-014R, 13-028R and 14-010R). The Sea Turtle Grants Program is funded from proceeds from the sale of the Florida sea Turtle License Plate. Learn more at www.helpingseaturtles.org. The US National Science Foundation supported SAC Research-in-Residence at the University of Denver (Colorado) through the Inter-university Training for Continental-scale Ecology (ITCE) program.
The authors declare that they have no competing interests.
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Ceriani, S.A., Weishampel, J.F., Ehrhart, L.M. et al. Foraging and recruitment hotspot dynamics for the largest Atlantic loggerhead turtle rookery. Sci Rep 7, 16894 (2017). https://doi.org/10.1038/s41598-017-17206-3
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