Introduction

Increasing anthropogenic and climatic stressors on Earth ecosystems have motivated a widespread interest in understanding the contribution of species to ecosystem functioning and energy flows between ecological compartments such as trophic guilds. Among marine environments, coral reefs are by far the most diverse ecosystems, hosting thousands of species forming vast, complex and very poorly resolved interaction networks that influence the structure, the functioning and the resilience of the ecosystems1. However, understanding the processes that drive ecosystem functioning and productivity requires determination of the major sources of organic matter fueling these systems2, and the stocks of nutrients3, and quantification of the numerous consumer compartments that rely on sources of organic matter4, 5. Elucidating the major energetic pathways that fuel ecosystems across the complexity of the interaction network is crucial not only to assess food web functioning and the resilience of coral reefs but also to anticipate unexpected cascading effects and undesirable ecological surprises related to global changes6,7,8.

Several studies have improved our understanding about flows of energy within coral reefs4, 9,10,11,12,13 but the processes involved, the species that support them and the ways these species interact are scarcely resolved. For instance, the high diversity of sources of organic matter available to primary consumers complicates the characterization of energy flows2, 3, 14. Carbon sources may have several origins, continental or marine, and can come from coastal, pelagic or deep waters, and also from living organisms or detrital matter15, 16. Oceanic phyto- and zoo-plankton may also be imported into reefs by currents, and then consumed by phyto- and zoo-planktivorous fish17, 18. While benthic sources represent an important carbon source to reef species4, 12, 19, numerous species rely principally or exclusively on planktonic sources20 and even non-planktivorous species may rely on oceanic production12. However, in several ecosystems, benthic production and/or terrestrial inputs can also be major contributors to the energy flow in food webs2, 3, 21.

The Marquesas Islands, one of the most isolated archipelagos on Earth, may provide important insights into the functioning of coral reefs characterized by low diversity and low coral cover. Decreasing coral cover and diversity are expected in many reef systems in the world facing increasing anthropogenic pressures22,23,24,25,26. Marquesas Islands coral reefs could not track sea level rise during the last post-glacial period27, and paleo-reefs can now be found at ~ 60–130 m depth, while modern shallow reefs are essentially rocky reefs with low coral cover. Other distinctive features of the Marquesas include the absence of Acropora spp. corals, which are common across other Polynesian coral reefs28. On one of the main islands of the Marquesas, Nuku Hiva, mean coral cover is only ~ 5%29. Other environmental conditions that make the Marquesas a highly pertinent system for the study of the functioning of their food web are their warm waters and high nutrient levels. The sea surface temperature is usually relatively high all year round (average 28–30°C3, 28), and sometimes higher during ENSO events, and thus substantially warmer than on several other reef systems like those located at higher latitudes and experiencing wider seasonal differences. Surface waters have high loads of nitrate (NO3) and phosphate (PO4), with concentrations higher than 1 μM and 0.3 μM, respectively, which exceed ~ 100-fold those measured in the South Pacific subtropical gyre30. This nutrient richness promotes the development of a high phytoplankton biomass around the Marquesan coasts over the year30.

In coral reef systems worldwide, the questions of ecosystem functioning, food web structure and function and organic matter sources fueling production are gaining attention4, 11, 13, 31. Here we characterize the major energetic pathways that fuel the unusual, low coral cover ecosystem of the Marquesas and assess the extent to which this pelagic production penetrates the coral reef food web. We analysed the trophic relationships among the food web components (sources of organic matter, primary consumers and higher trophic level consumers up to mesopredators) using multiple and complementary trophic markers. We combined information from carbon (δ13C) and nitrogen (δ15N) bulk stable isotope compositions, amino acid compound-specific isotopes compositions (δ15N) (AA CSIA) and fatty acids data. These three trophic have evidently yet to be combined to analyse any coral reef ecosystems, although they are capable of providing highly complementary information. Fatty acids are used to assess how the various sources of organic matter are integrated by primary consumers (herbivores) and then by secondary consumers, AA-CSIA provide information on both the assimilated baseline and the length of food chains, while bulk stable isotope analyses allow to describe the global structure of the food web. The combination of these methods allowed us to address five major questions: (i) What are the main sources of organic matter that fuel the food web of the Marquesas coral reefs, and (ii) how is this organic matter integrated by primary consumers? What is (iii) the trophic structure of this system, and (iv) the ‘baseline’ allowing us to assess the length of the food chain? (v) Is the uptake of the major sources of organic matter consistent across seasons? We then interpreted the observed patterns in the light of previous observations on other reef systems to draw inferences about possible coral reef functioning in future warming and possibly more eutrophic tropical oceans.

Material and methods

Study site and sampling

Field work was carried out in August 2016 (austral winter) and in March 2017 (austral summer) in southeastern Nuku Hiva (8°54’S, 140°02’W; Marquesas Islands, French Polynesia). The abiotic (rainfall, winds, temperature, hydrodynamics, etc.) and biotic (benthic and pelagic communities) conditions around the islands are well known3, 28, 32.

We sampled the major sources of organic matter (OM), primary consumers (invertebrates and fish) and several higher trophic-level consumers (invertebrates and fish), up to mesopredators. The sampling of OM sources, already described in detail2, comprise the particulate OM-hereafter POM mainly consisting of pico-nano phytoplankton–(n = 49), sedimentary OM-hereafter SOM-(n = 47), micro-phytoplankton-hereafter phytoplankton-(n = 49), 11 different locally abundant algae (algal turf and macroalgae, n = 73) and detrital terrestrial material-hereafter DTP-derived from tree leaves transported by rivers (n = 16).

The sampled consumers were 14 invertebrate species (sponges, ascidians, echinoderms, gastropods, bivalves and crustaceans-214 individuals in total), zooplankton (n = 49), and 29 fish species (n = 523). Invertebrates were collected by handpicking during scuba diving, in order to obtain 5–10 individuals per species and per season. For zooplankton, a 125 µm mesh-size WP2 net was used for a vertical tow in the water column (from ~ 40–50 m depth to the surface). Fish were collected by spearfishing or using an anesthetic (i.e. eugenol diluted at 10% in alcohol), in both seasons. All samples were identified to the lowest possible taxonomic level and were kept in ice chests during sampling and (except for POM, phyto- and zoo-plankton) immediately stored at − 20 °C until analysis.

First, we restricted our analysis to species representative of well-known trophic groups across the trophic-level gradient in order (i) to determine how the organic matter is assimilated by primary consumers, and (ii) to assess the length of the food chain. We selected nine primary consumers to study the integration of OM sources. Among these species, three were filter-feeders (the oyster Pinctada margaritifera, an unidentified ascidian, the sponge Spheciospongia sp.), one was a phytoplankton browser (zooplankton either 300–500 µm or 1000–2000 µm in size), and five were herbivore-detritivores (the gastropods Mauritia spp., the surgeonfishes Acanthurus nigricans and Ctenochaetus marginatus, and the parrotfishes Scarus koputea and S. rubroviolaceus). We also selected eight secondary-tertiary consumers expected to be at the top of the benthic food webs. These species were one gastropod, Conus conco, and seven fish: the snappers Lutjanus bohar, L. gibbus, and L. kasmira, the moray-eel Enchelycore pardalis, the scorpionfish Scorpaenopis possi, and the groupers Cephalopholis argus and Epinephelus fasciatus.

Then, we extended our analysis to all the species for which samples were available, i.e. the 14 invertebrate and 29 fish species collected. We defined the trophic position of all individuals in order to assess their position in the food web relative to the baseline, i.e. linked to OM sources.

Thus, the first analysis, focused on well-known trophic groups, allowed us to determine how the OM is incorporated and what the length of the food chain is. Then, the inclusion of all species allowed depiction of the food-web structure.

Bulk stable isotope analyses

These analyses were run to get a general picture of the food web structure, the role of the OM sources and of various primary and secondary-tertiary consumers within the food web. The carbon and nitrogen stable isotopes (respectively δ13C and δ15N) were used in combination; δ13C give information on the origin(s) of the organic matter source(s) used by consumers33 and δ15N is a proxy of trophic level34, thus allowing a depiction of the food webs in bivariate isotopic space35.

A piece of the thallus was sampled for algae, soft muscle for all mollusks, and dorsal white muscle for fish36,  ~ 2–5 g in each case. For ascidians and sponges, ~ 5–10 g pieces, excluding external theca for ascidians, were taken from each individual. For zooplankton, several entire individuals were grouped to obtain the 5 mg dry mass required for analysis.

Carbon and nitrogen bulk stable isotope compositions (δ13C and δ15N) were determined in all samples. Sediment was dried and reduced to a fine powder using a mortar and pestle. POM was collected on precombusted GF/F filters (porosity 0.7 µm), and dried. Plant (algae, DTP) and animal (zooplankton, invertebrates and fish) samples were freeze-dried and ground to fine powder. Approximately 1 mg of powder was precisely weighed and encapsulated for plant/animal samples, and 15–20 mg for SOM and 15–30 mg for POM and phytoplankton (matter extracted by scrapping the filter). For POM and SOM, two subsamples were analyzed: one was acidified to eliminate inorganic carbonates from the sample and used for δ13C analysis37, while the other was not acidified and used for δ15N analysis43. The other samples were analyzed without prior treatment. Samples were analyzed through continuous-flow isotope-ratio mass spectrometry with a Flash 2000 elemental analyzer equipped with the Smart EA option (Thermo Scientific, Milan, Italy), coupled with a Delta V Advantage isotope ratio mass spectrometer with a Conflo IV interface (Thermo Scientific, Bremen, Germany) at the Littoral, Environment and Societies Joint Research Unit stable isotope facility (LIENSs) at the University of La Rochelle (France). Isotope compositions were expressed in the δ notation as parts per mil (‰) as deviations from an international standard (i.e. Vienna Pee Dee Belemnite for carbon and atmospheric N2 for nitrogen) following the formula:

$$\delta {\mathrm{X}} = \left[ {\left( {{\mathrm{R}}_{{\mathrm{sample}}} /{\mathrm{R}}_{{\mathrm{standard}}} } \right) - 1} \right]{ \times }1000$$

where X is 13C or 15N, R is the corresponding ratio (13C/12C or 15N/14N). Calibration was done using reference materials (USGS-24, -61, -62, IAEA-CH6, -600 for carbon; USGS-61, -62, IAEA-N2, –NO-3, -600 for nitrogen). The analytical precision of the measurements was 0.1‰ for carbon and < 0.15‰ for nitrogen based on analyses of USGS-61 and USGS-62 used as laboratory internal standards.

Compound-specific amino acid stable isotope analyses

These analyses were run to (i) help define the ‘baseline’ of the food web through the use of sources amino acids, and (ii) to assess food chain length through both trophic amino acids and bulk stable isotopes. Sr-AA δ 15N values capture the real baseline isotopic composition much better than those of bulk δ15N because the latter value pool several amino acids, whereas Sr-AA δ15N values do not fluctuate over different trophic levels, thus capturing the baseline isotope composition of the food web without biases5.

Compound-specific δ15N values of amino acids (AA-CSIA) were derived from eight selected species having high bulk δ15N values (see above). This included the gastropod and the seven secondary-tertiary consumer fish species (total 44 samples for both seasons). Samples were prepared by acid hydrolysis followed by derivatization to produce trifluoroacetic amino acid esters (TFAA) using standard methods38. The δ15N values of the TFAA derivatives of amino acids were analyzed using a isotope ratio mass spectrometer (Delta V Plus, Thermo Scientific, Bremen, Germany) interfaced with a gas chromatograph (Trace GC 1300, Thermo Scientific, Bremen, Germany) through a GC IsoLink combustion furnace, and liquid nitrogen cold trap at the University of Davis (California, USA). Measured isotopic values were corrected relative to known δ15N values of norleucine, the internal reference material. All samples were analyzed in triplicate. δ15N values of the glycine and phenylalanine were then measured for source amino acids (δ15NSr-AA) in order to assess the baseline δ15N values (i.e. the δ15N of the primary producers at the base of the food web5, 39). So, knowing characteristics of main organic matter sources by one hand (i.e. the ‘baseline’), and knowing species at the top of the food web on the other hand (i.e. the eight selected species), we expected to be able to assess the food chain length.

Trophic positions

We estimated the trophic position (hereafter TP) of several individuals using a combination of AA-CSIA and bulk SIA. In particular, we used the δ15N values from bulk SIA of target individuals and from AA-CSIA to characterize the baseline. Then, TP was calculated as follows40:

$${\text{TP}}_{{\text{x}}} = \frac{{{\updelta }^{15} {\text{N}}_{{\text{x}}} - {{ \delta }}^{15} {\text{N}}_{{{\text{baseline}}}} }}{{{\text{TEF}}}} + {\text{ TP}}_{{{\text{baseline}}}}$$
(1)

where x is the species of interest and TEF is the trophic enrichment factor between trophic levels. In our case, we set the TEF at 3.4 ‰ as commonly done in the marine coastal environment40. Because the source amino acids (glycine, phenylalanine) represent the δ15N value of the baseline, a TPbaseline of 1 was used.

Fatty acid analyses

These analyses were run to assess the integration of OM sources by primary producers and possibly the use of these herbivores by secondary-tertiary consumers.

Fatty acid (FA) were analysed in the OM sources (SOM, river and marine POM, DTP, algae and phytoplankton2) and in nine primary consumers: zooplankton (n = 23), four invertebrate species (n = 54) and four fish species (n = 56). Lipids were extracted41, using 5–20 mg of material for POM, 20–30 mg for DTP, algae, phyto- and zooplankton, sponges and ascidians, 30–40 mg for mollusks and fish and 1 g for SOM. Tricosanoic acid (23:0), was added to each sample as an internal standard to measure the FA concentrations. Fatty acid methyl esters (FAMEs) were quantified by gas chromatography (Varian 3800-GC), using a flame ionization detector. FAs were identified by comparing retention times with those of a commercial standard (Supelco) and confirmed using a mass spectrometer coupled to a gas chromatograph (Varian 450-GC; Varian 220-MS). Fatty acid concentrations are expressed as % of total FAs, or as absolute concentrations in mg.g−1.

Functional groups of fatty acids, classified by degree of unsaturation, were used as indicators of different types of organic matter42, 43: the saturated fatty acids (SFAs; e.g. 14:0, 16:0 and 18:0), monounsaturated fatty acids (MUFAs; e.g. 16:1ω7 and 18:1ω9), polyunsaturated fatty acids (PUFAs; e.g. 20:4ω6, 20:5ω3 and 22:6ω3) and branched fatty acids (BrFAs; e.g. iso-15:0 and anteiso-15:0). Among SFAs, the long-chain SFAs (C24-C28) are widely used as an indicator of detrital terrestrial plant (DTP) material44. Bacteria and cyanobacteria are also rich in SFAs45. C16 and C18 MUFAs are found in algae46, bacteria47 and zooplankton48. PUFAs with an omega-3 (ω3) or omega-6 (ω6) terminal end are named essential fatty acids (EFAs) because animals are considered typically to acquire them solely from diet45. PUFAs are abundant in fresh plankton material (major components of phytoplankton), but these FAs are rapidly degraded in the water column and the sediment49, 50. Iso- and anteiso-FAs (BrFAs) are solely synthesized by bacteria and therefore are deemed to be a good indicator of these microorganisms47, 51.

Assessment of OM integration by primary consumers

Assessment of food source uses by primary consumers was achieved through two complementary methods. The first approach is based on the close relationship between the isotope compositions of a consumer and its food sources52. The contributions of the different sources to the diets of primary consumers (i.e. macroalgae, algal turf, phytoplankton, POM and/or SOM) were determined using a Bayesian mixing model and the SIAR package53. OM sources with similar isotope composition were pooled to avoid incorrect determination of their relative contribution. Models were run for 200,000 iterations, the burn-in was set at 50,000 iterations and a one-fifteenth thinning was applied. This model provides a range of solutions regarding the proportions of the different sources (i.e. macroalgae, algal turf, phytoplankton, POM and/or SOM). To reduce potential bias associated with the definition of a single trophic enrichment factor (i.e. 3.4‰), we also used TEF (Δ13C and Δ15N) values adapted to the feeding strategies and trophic positions of the studied taxa (Suppl. Figure S1). The determination of Δ13C and Δ15N values was based on the isotope compositions of the primary consumers (see results) in combination with previous findings3 on OM sources. The herbivore-detritivores showed TEFs values of 1.60 ± 1.87‰ for Δ13C and 4.28 ± 1.05‰ for Δ15N, while filter-feeders and zooplankton had 1.24 ± 1.16‰ for Δ13C and 2.71 ± 0.85‰ for Δ15N.

The second approach was based on the exploration of the links between FAs and primary consumers through a principal component analysis (PCA), using the 25 individual FAs that had an average proportion greater than 1% within at least one group of samples. The statistics and graphical representations were performed using R version 3.4.454, using ggplot2, gridExtra, ggrepel, vegan, FactoMiner and car packages. Identification of FAs bio-indicating particular OM sources allowed us to assess the importance of the integration of various potential OM sources by primary consumers.

Ethical statement

This research received no specific grant from any commercial or not-profit sectors. No coral habitat was degraded during this research. Sample collection was permitted by the French Polynesian government (authorization number: 681/MCE/ENV), which also approved the experimental protocols. All methods were carried out in accordance with relevant guidelines and regulations. All methods were performed in compliance with the ARRIVE guidelines and regulations for ethical treatment of animals55.

Results

OM sources in the Marquesan coastal ecosystem

As the data on the different potential sources of organic matter were already widely presented and discussed in a previous article42, only a brief outline is given hereafter. The mean δ13C values ranged from − 23.9 ± 1.7‰ for algal turf to − 16.4 ± 2.0‰ for macroalgae (3, Suppl. Table 1). The mean δ15N values ranged from 11.6 ± 0.9‰ for macroalgae to 15.0 ± 1.8‰ for phytoplankton (3, Suppl. Table S1).

Primary consumers: trophic marker characteristics and use of OM sources

Mean δ13C values ranged from − 19.6 ± 2.7 (Acanthurus nigricans) to − 14.0 ± 1.3‰ (Ctenochaetus marginatus) in winter, and from − 20.2 ± 0.5 (small zooplankton) to − 13.9 ± 1.2‰ (C. marginatus) in summer (Table 1). Mean δ15N values ranged from 12.6 ± 0.9 (small zooplankton) to 19.1 ± 1.0‰ (C. marginatus) in winter, and from 14.2 ± 0.4 (Pinctada margaritifera) to 17.4 ± 1.4‰ (C. marginatus) in summer. The parrotfish and cypraeid species did not differ significantly from each other in mean δ13C and δ15N values (Table 1, Kruskal–Wallis tests, P > 0.05) and were hereafter pooled with Mauritia spp. and Scarinae, respectively.

Table 1 Bulk δ13C and δ15N values (means ± standard deviation) of nine selected primary consumers.

We detected 57 FAs, of which 35 had concentrations greater than 1% (see Suppl. Table S2 for details). The two size groups of zooplankton had similar fatty acid compositions (Kruskal–Wallis test, P > 0.05) and were thus pooled hereafter. The sponge Spheciospongia sp. represented an outlier with extremely high percentages of several SFAs, MUFAs and mostly PUFAs (Suppl. Table S2), and was therefore removed from further analyses.

Different primary consumers were characterized by different FA profiles (Fig. 1, Suppl. Table S2). For instance, zooplankton was mostly characterized by some SFAs (14:0 and 15:0), MUFAs (16:1ω7) and PUFAs (16:2ω4 and 20:5ω3) (Fig. 1). Scarinae were mostly characterized by 16:0 and 18:0 (SFA), 18:1ω9, 20:4ω6, 22:5ω6 (PUFAs), and 22:6ω3, whereas Acanthurus nigricans was characterized by 16:0 (SFA) and 18:1ω9 (Fig. 1, Suppl. Table S2).

Figure 1
figure 1

PCA of fatty acid (FA) compositions of the invertebrates (excluding sponges) and fishes. Codes of species: Asc: ascidians, Pima: Pinctada margaritifera, Maspp: Mauritia spp., Zoo: zooplankton, Acni: Acanthurus nigricans, Ctma: Ctenochaetus marginatus, Scar: Scarus koputea and S. rubroviolaceus. Only FAs with a mean percentage > 1% in at least one species were considered (see text).

We detected differences in the use of major sources of OM among seasons for zooplankton and herbivore-detritivores (Fig. 2). Small zooplankton mostly relied on POM in both seasons (~ 60% on average, credibility interval (CI) ~ 30–85%), with phytoplankton contributing ~ 20–30% to isotope composition (CI ~ 0–60%). Large zooplankton relied mostly on POM during winter (~ 60%, CI ~ 40–85%) and on phytoplankton during summer (~ 75%, CI ~ 50–100%) (Fig. 2). Similar seasonal differences occurred in the filter-feeders, although with a much lower amplitude. The major sources of OM for ascidians were phytoplankton, algae and POM in relatively equal proportions (~ 25–40% depending on seasons); the sponge Spheciospongia sp. did not use a lot of POM, and Pinctada margaritifera relied mainly on macroalgae, and less on POM and phytoplankton (Fig. 2). SOM and macroalgae were important OM sources for herbivore-detritivores but with a strong seasonal contrast in some cases, ranging from ~ 10% (Acanthurus nigricans in summer) to ~ 90% (Ctenochaetus marginatus in winter) and from ~ 10% (C. marginatus in winter) to ~ 75% (C. marginatus in summer), respectively (Fig. 2). Algal turf was a marginal OM source for Scarinae and C. marginatus, contributing ~ 10–15% to the isotope composition of Mauritia spp. and up to ~ 50% (in winter) to that of A. nigricans.

Figure 2
figure 2

Relative proportions of the different OM sources for filter-feeders and zooplankton (left panel) and for herbivore-detritivores (right panel), based on SIAR mixing model outputs. Phytopk: Phytoplankton; POM: particulate organic matter; SOM: sedimentary organic matter. Violin plots represent the posterior distribution shape of the data (density estimation) in grey; boxplots represent median, interquartile ranges (red and blue boxes, depending on season), 95% credibility intervals (thin line) and outliers (black dots). ZOO-300: zooplankton 300–500 μm, ZOO-1000: zooplankton 1000–2000 μm, ASSP: ascidians, SPSP: Spheciospongia sp., PIMA: Pinctada margaritifera, ACNI: Acanthurus nigricans, CTMA: Ctenochaetus marginatus, SCAR: Scarinae (Scarus koputea and S. rubroviolaceus), MASPP: Mauritia spp.

Secondary consumers trophic markers and the general structure of the food web

Based on bulk isotope compositions of OM sources, nine primary consumers and eight secondary-tertiary consumers, we were able to delineate the general structure of the major energetic pathways of the Marquesan coastal food web (Fig. 3). For secondary-tertiary consumers, mean bulk δ13C values ranged from − 16.5 to − 14.7‰, and those of δ15N values ranged from to 18.7 to 20.4‰ (Fig. 3). The highest mean δ15N values were measured in the endemic gastropod Conus conco and the grouper Cephalopholis argus (20.4 ± 0.9‰ and 20.3 ± 0.4‰, respectively). For most secondary-tertiary consumers, differences between seasons were often low and non-significant (Suppl. Table S3). Other sampled consumer species not included in Fig. 3 for clarity fitted well within this network based on their δ13C and δ15N values (Suppl. Table S3).

Figure 3
figure 3

Plot of δ15N against δ13C values (means ± standard deviations) of sources of organic matter (black squares, see Fey et al. 2020 for details), nine primary consumers (red circles: invertebrates, green triangles: fish), and eight secondary consumers (blue circle: invertebrate, blue triangles: fish), both seasons pooled. Turf: algal turf, Phyto: phytoplankton, Algae: macroalgae, POM: particulate organic matter, SOM: sedimentary organic matter, Asc: ascidians, Spsp: Speciospongia sp., Pima: Pinctada margaritifera, Maspp: Mauritia spp., Zoo: zooplankton, Acni: Acanthurus nigricans, Ctma: Ctenochaetus marginatus, Scar: Scarinae, Coco: Conus conco, Lubo: Lutjanus bohar, Lugi: L. gibbus, Luka: L. kasmira, Enpa: Enchelycore pardalis, Scpo: Scorpaenopsis possi, Cear: Cephalopholis argus, Epfa: Epinephelus fasciatus.

On average, the mean δ15N value of Sr-AA (phenylalanine and glycine) was 11.6 ± 3.4‰ with values ranging from 7.1‰ for glycine in Lutjanus bohar to 17.0‰ for phenylalanine in Conus conco (Table 2). Differences in Sr-AA δ15N values among species were more evident for glycine than for phenylalanine.

Table 2 Table 2

The eight secondary consumers also displayed seasonal differences in both their mean bulk δ15N and Sr-AA δ15N values (Fig. 4), although not statistically significant, mean values were higher in winter than summer, in contrast to what was observed for bulk δ15N values of phytoplankton and macroalgae (Fig. 4).

Figure 4
figure 4

Seasonal variations of bulk δ15N values (means ± standard deviation) for the most integrated primary producers (left panel), and bulk, and Sr-AA (phenylalanine and glycine) for our eight targeted secondary consumers, all species pooled (right panel). Blue dots: winter, red triangles: summer.

Baseline and trophic positions

Although the isotope compositions of primary consumers evidenced the use of several OM sources (Fig. 2), the relatively high concentrations of the fatty acid 20:4ω6, a biomarker of macroalgae, in all primary consumers (even for zooplankton although at lower concentrations) allowed us to identify in the macroalgae the main baseline to estimate TP. The Sr-AA δ15Nphe-gly values obtained for the eight mesopredators were also used.

The mean bulk δ15N values of all individuals (n = 797) and species (n = 43) belonging to different trophic groups (Suppl. Table S3) provided a detailed picture of their trophic positions in the food web (Fig. 5). Most primary consumers (i.e. filter-feeders, zooplankton and herbivores) displayed a TP of ~ 2–2.3, omnivores and detritivores had a TP of ~ 2.4–3, carnivores were at a TP ~ 3–3.2 and piscivores showed a TP of ~ 3.2–3.6, with the highest TP being in Conus conco and Cephalopholis argus (3.57 ± 0.27 and 3.55 ± 0.23, respectively; Fig. 5). This global picture was consistent across seasons for all trophic groups, despite higher δ15N values in summer than in winter (Suppl. Figure S2).

Figure 5
figure 5

source of organic matter. Each dot corresponds to the mean TP for a species. Black circles for sources of organic matter, red circles for invertebrates, and green circles for fish.

Relationships between mean bulk δ15N values and trophic positions (TPs) calculated with Sr-AA δ15Nphe-gly values and with macroalgae as the main

Discussion

We provide the first combined application of bulk and compound specific stable isotope as well as fatty acid data to a coral reef food web, and elucidate food web functioning including major energetic pathways, OM sources and trophic positions of multiple species on a Marquesan coral reef. Despite the peculiar ecological characteristics of these coral reefs (warm water, high nutrient levels, low coral cover as well as reduced biodiversity compared to many other reefs), fatty acid, C and N stable isotope data evidenced that this system maintains a high productivity fueled by phytoplankton and zooplankton, most likely of pelagic origin. Moreover, despite unusually high δ15N values for all groups from OM sources up to mesopredators, trophic positions and food chain lengths were comparable to those documented for other coral reef ecosystems56, 57. Since conditions experienced in the Marquesas today are projected for many other reef systems in the future, this study offers valuable insights into the future of changing coral reefs.

The outputs from mixing models highlighted that macroalgae, phytoplankton, POM and SOM are the main sources of OM for the consumers of the Marquesas, while turf algae had a comparatively minor role. Algal turf is often described as a major OM sources in coral reefs, especially for herbivorous fish4, 10, 58, 59. However, at Nuku Hiva, it contributed only ~ 15% to herbivores, although in Acanthurus nigricans its contribution to biomass reached ~ 50% in winter. In a complex coral reef system in New Caledonia, four major sources of OM used by consumers were evidenced2, i.e. algal turf (the most important one), sedimentary OM mixed with macroalgae, particulate OM, and -to a lower extent- detritus and seagrass. In a Caribbean coral reef, algal turf is also the main OM source for consumers57. The reasons for a marginal importance of algal turf in Marquesas Islands remain unclear. Algal turf may lack important nutritive elements60 inducing herbivores to shift their diet to other items, such as macroalgae. In contrast to macroalgae, algal turf in Marquesas displayed a high C/N ratio (~ 183), much higher than the value of ~ 12 usually considered as characteristic of refractory organic matter61. This suggests a low nutritional value of this food item and might explain why algal turf was little used in Marquesas, despite its wide distribution. The reason for such a C/N ratio remains unclear and requires further investigations.

The FA compositions of the primary consumers also highlighted the importance of the macroalgae in the food web. Indeed, we detected a high abundance of the FAs 18:3ω3 and 20:4ω6 in all primary consumers (Fig. 6). Diatom markers (20:5ω3, 16:1ω7 and 16:2ω4) were also present in primary consumers, especially zooplankton, ascidians, and the detritivore-herbivores Acanthurus nigricans and Ctenochaetus marginatus. Although we did not sample bacteria/cyanobacteria, markers typical of these organisms (FAs 15:0, 17:0, 17:0iso, and 18:1ω7) were found in ascidians, Pinctada margaritifera and all fish. This suggest a potential role of bacteria in the Marquesan food web. Bacteria have not been previously shown to contribute substantially to the OM that support reef fishes. Therefore, future studies are needed to clarify their contribution. Cyanobacteria have been recorded on several herbivores fish diets such as in Scarus spp.62. Our FA data however cannot distinguish between filamentous turf-forming species and non-colonial small species. The strong contribution of the fatty acid 22:6ω3, a marker of dinoflagellates found in phytoplankton3, to the total FAs of zooplankton, P. margaritifera, C. marginatus and Scarus spp. indicated that phytoplankton was an important food source not only for zooplankton, but also for filter-feeders and some herbivores. However, we did not identify an important contribution of phytoplankton-derived OM for Acanthuridae and Scarinae, even though these taxa occasionally feed on zooplankton and indirectly assimilate phytoplankton-derived OM63. We suggest that the link between this OM source and these primary consumers is probably indirect, through deposition and accumulation of recently dead phytoplankton (or zooplankton) on sediments and macroalgae.

Figure 6
figure 6

Schematic view of the integration of main OM sources by primary consumers, through fatty acid trophic markers. The relative importance of such integration is indicated by arrows (from dotted lines for minor role, to thick lines for important role). POM: particulate organic matter, SOM: sedimentary organic matter, DTP: detrital terrestrial plant material. For OM pools (POM and SOM), the % indicate the relative importance of primary producers (bacteria, phytoplankton, DTP etc.) assessed by major FAs trophic markers.

The compound specific stable isotopes (Sr-AA δ15Nphe-gly) allowed us to define the δ15N values of the food web baseline. These values were higher in winter than in summer (Fig. 4), in contrast to the seasonal variability recorded in bulk isotope compositions. This apparent contradiction may be due to a temporal lag. Indeed, the isotope compositions of the source amino acids were measured on consumer, which likely have a longer turn-over than primary producers. Also, the estimated δ15N values of the food web baseline obtained with bulk stable isotope data reflected relatively recent variations of isotope composition (i.e. isotope composition of the OM sources at the time of collection, typical of the sampled season). In contrast, the amino acid isotope compositions provided a value of the sources referred to a longer time frame corresponding to the renewal time of the tissues analyzed, i.e. ~ 3 months before sampling for fish muscle.

The unusually high bulk δ15N values of OM sources up to mesopredators suggest a high δ15N value of the food web baseline that then propagates through the system. It is thus essential to understand why this pattern exists and why δ15N values remain high across seasons despite winter / summer fluctuations (Fig. 7). The δ15N values measured in the primary producers in the Marquesas were ~ 8–10‰ higher than in other Pacific sites2, 9, 10, 64. These δ15N values are probably due to the 15N enrichment of nutrient reservoirs in Marquesan waters, and seasonal changes in the strength of hydrodynamic processes such as eddies and upwelling32. δ15N values increase in declining nitrate reservoirs, due to the more rapid assimilation of nitrates containing the light isotope (14N) during photosynthesis65. The high phytoplankton biomass throughout the year in the Marquesas Islands30, and its use of nitrate (NO3) helps explain the 15N enrichment of the reservoirs of residual nutrients66. In the Marquesas, the high nutrient intake in summer may promote significant fractioning and enhance the δ15N values of the residual nitrate65, 67 (Fig. 7). By assimilating 15N-enriched nitrates, primary producers such as phytoplankton and macroalgae thus increase their δ15N values. This is not the case for turf algae that sustain similar δ15N values over seasons. Other processes may drive the 15 N enrichment of nitrates and primary producers, such as higher bacterial denitrification in summer65, a possibly important role of bacteria in the functioning of the Marquesan coral reef ecosystem. Mineralization, nitrogen fixation, assimilation, nitrification and/or denitrification processes influence the 15N composition of both inorganic (e.g. N2, NO3, NO2) and organic nitrogen species50.

Figure 7
figure 7

Schematic view of seasonal processes that could explain seasonal differences in nitrogen isotope compositions in primary producers.

The assessment of trophic positions (TPs) of organisms within food webs is essential to understand ecosystem structure and functioning68, although a thorough quantification remains challenging given the large number of factors involved (e.g. ontogeny of species, change of dietary regime). The δ15N values of the source amino acids phenylalanine and glycine indicate that the Marquesan coastal food web is mostly supported by macroalgae. However, the high variability around the mean implies that this finding should be considered with some caution. Seasonal fluctuations in phytoplankton isotope composition in the Marquesas make this compartment an important food source for several primary consumers3. This suggests that coupled pelagic-benthic processes likely drive the general characteristics and properties of OM sources over seasons. The TP values found in other studies are close to ours, despite very different bulk δ15N values. For instance in a Caribbean coral reef, the five carnivorous fish having the highest TPs reached values of ~ 3.3, for bulk δ15N values of ~ 9.5‰57. In a Polynesian coral reef, those values reached ~ 3.5 and ~ 11‰, respectively56. Overall, the TPs we obtained for the different species or trophic groups are very similar to those from these studies, implying similar food chain lengths.

The overall increase in the TP for all consumers in summer did not alter this general pattern. Under the hypothesis that the Marquesas may be considered a present-day reference for degraded reefs, the Nuku Hiva data suggest that the length of the food chain may remain unchanged in future coral reefs subject to anthropogenic degradations, as also observed in Mexico57. However, systems with similar food chain lengths may strongly differ in energy flows. For instance, the seasonality in TP values in the Marquesas, which were mostly apparent for omnivores and some carnivores (Suppl. Figure S2), also reflected a change in the use of OM and in the energy pathway within food webs. Coral losses alter isotope compositions of coral reef fish69. Since environmental changes may produce substantial effects on fish abundance and biomass70, ongoing coral reefs degradations may drastically affect fluxes of energy and ecosystem functioning7. While some coral reefs appeared to be resilient to disturbances, mostly thanks to herbivory71, a shift from coral towards algal reefs seems likely in the coming decades72,73,74. On such reefs, the role of macroalgae and plankton driven by nutrient enrichments especially for nitrogen might grow. Although the present Nuku Hiva data were mainly qualitative, a greater potential role of bacterial / cyanobacterial communities as significant sources of OM in future coastal systems needs more consideration than it has had to date75, 76.

Conclusions

Although some characteristics appear to be similar to other tropical reef systems, in many respects the food web functioning of the Marquesas Islands coral reef ecosystems is quite atypical. Fatty acid data highlighted that the roles of several sources of OM, such as bacteria / cyanobacteria which are generally difficult to collect in classical food web studies, may have been underestimated in other reef systems. Pelagic-derived OM may exceed the key-role of macroalgae as the main baseline of this food web. Similar conclusions regarding the importance of pelagic-derived organic matter as a food source for coral reefs were drawn from other studies13, 77. This reinforces the hypothesis of a food web based on pelagic-benthic coupling3, and suggests that such functioning might become an increasingly important characteristic in future coral reefs. Despite the unusually high δ15N values in all compartments of the studied food web, the trophic positions of consumers were comparable to other reef systems. Although this suggests that food chain lengths might not be much affected by the expected loss of corals, seasonal and more long-term variations in the use of OM by consumers will likely affect energy flows. Much further research is needed to better assess how coral reef flows of energy and organic matter might change in the next decades. The current Marquesa’ Islands coral reefs offer one plausible future scenario for functioning of this ecosystem. The resilience of the Marquesan reef ecosystem may be low and this raises concerns about its capacity to resist future changes.