Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Alien Marine Fishes Deplete Algal Biomass in the Eastern Mediterranean

  • Enric Sala ,

    esala@ngs.org

    Affiliations Centre d'Estudis Avançats de Blanes, Consejo Superior de Investigaciones Científicas, Blanes, Spain, National Geographic Society, Washington, D. C., United States of America

  • Zafer Kizilkaya,

    Affiliation SAD-EKOG, Maltepe, Ankara, Turkey

  • Derya Yildirim,

    Affiliation SAD-EKOG, Maltepe, Ankara, Turkey

  • Enric Ballesteros

    Affiliation Centre d'Estudis Avançats de Blanes, Consejo Superior de Investigaciones Científicas, Blanes, Spain

Abstract

One of the most degraded states of the Mediterranean rocky infralittoral ecosystem is a barren composed solely of bare rock and patches of crustose coralline algae. Barrens are typically created by the grazing action of large sea urchin populations. In 2008 we observed extensive areas almost devoid of erect algae, where sea urchins were rare, on the Mediterranean coast of Turkey. To determine the origin of those urchin-less ‘barrens’, we conducted a fish exclusion experiment. We found that, in the absence of fish grazing, a well-developed algal assemblage grew within three months. Underwater fish censuses and observations suggest that two alien herbivorous fish from the Red Sea (Siganus luridus and S. rivulatus) are responsible for the creation and maintenance of these benthic communities with extremely low biomass. The shift from well-developed native algal assemblages to ‘barrens’ implies a dramatic decline in biogenic habitat complexity, biodiversity and biomass. A targeted Siganus fishery could help restore the macroalgal beds of the rocky infralittoral on the Turkish coast.

Introduction

The Mediterranean is a microcosm of the major threats to the oceans – historical overfishing, habitat degradation, pollution, introduced species, and global warming [1]. On shallow rocky habitats, the confluence of some of these stressors helps to create one of the most degraded underwater communities in the Mediterranean – infralittoral barrens. These barrens are impoverished bottoms dominated by bare rock with a few species of encrusting algae, caused typically by the grazing action of abundant sea urchins Paracentrotus lividus and Arbacia lixula [2], [3], [4]. In 2008 we observed extensive areas (several hundred meters in length) devoid of any erect macroalgae at several locations in the Mediterranean coast of Turkey, but sea urchin abundance was surprisingly low (Fig. 1). These areas (hereafter called ‘barrens’) were similar to sea urchin barrens but with small turfs of small filamentous algae and Padina pavonica during the season of highest algal production (spring-summer), although afterwards most visible algae disappeared (see results).

thumbnail
Figure 1. Infralittoral barrens at 10 m depth near Kas, Turkey, May 2008.

Note the absence of erect algae and sea urchins.

https://doi.org/10.1371/journal.pone.0017356.g001

Plausible explanations for the existence of these barrens included low nutrient concentrations and fish grazing. We discarded nutrient concentrations as the cause because benthic algae were abundant on the uppermost wave-washed infralittoral zone, and also abundant in other locations situated only kilometers away. Herbivorous fish appeared to be abundant at the barrens, especially the alien rabbitfish Siganus luridus and S. rivulatus, which formed schools of up to several hundred individuals each.

Siganus rivulatus entered the Mediterranean through the Suez Canal in 1927 [5], and S. luridus appeared in 1956 [6]. Since their introduction they have established large populations in the Eastern Mediterranean [7], and S. luridus has even been found in the western Mediterranean as far as Marseille [8]. These alien fish, however, had not been reported to have a dramatic effect on the Mediterranean benthos [9].

To test whether fish grazing – and in particular grazing by Siganus – was responsible for the creation of the observed denuded areas we conducted a fish exclusion experiment at three sites (Fig. 2) on the Mediterranean coast of Turkey.

Results

The biomass of herbivorous fish represented between 46% and 57% of the total fish biomass at the study sites (Table 1), and it was significantly greater than the biomass of other fish trophic groups at Kas (ANOVA, p<0.001) and Bodrum (p<0.01). The rabbitfish Siganus luridus and S. rivulatus together accounted for between 83% and 95% of the biomass of herbivorous fish at the study sites (Table 2). Sparisoma cretense was the only other major herbivorous fish observed at the study sites, but its biomass accounted for between only 5% and 17% of total herbivore biomass. The major native Mediterranean herbivorous fish Sarpa salpa, and sea urchins were not observed within our transects at the study sites.

thumbnail
Table 1. Biomass of fish trophic groups (g m−2; mean ± S.E., n = 6) and percentage of total fish biomass at the three study sites.

https://doi.org/10.1371/journal.pone.0017356.t001

thumbnail
Table 2. Percentage of the total herbivorous fish biomass accounted for by the four major herbivorous species.

https://doi.org/10.1371/journal.pone.0017356.t002

At the beginning of the experiment in March 2009, algal biomass was less than 5 g m−2 (Fig. 3). Algal biomass, including abundant canopy-forming brown algae of the genus Cystoseira (Fig. 4), grew significantly more inside the cages than in controls at all sites (ANOVA; interaction time × treatment, p<0.001; Fig. 3), but the increase in algal biomass in cages relative to controls was significantly different between sites (interaction site × time × treatment, p = 0.03). Algal biomass inside the cages at Kas was significantly greater than at Fethiye and Bodrum (p<0.001), but there were no significant differences between Fethiye and Bodrum. Algae declined in summer at Fethiye and Kas, and after October in Bodrum.

thumbnail
Figure 3. Evolution of total algal biomass inside the fish exclusion cages and controls (mean ± S.E., n  = 12) at the three study sites.

https://doi.org/10.1371/journal.pone.0017356.g003

thumbnail
Figure 4. An exclusion cage at Kas in August 2009, five months after the beginning of the experiment.

Inside the cage there is a well-developed algal assemblage, in contrast to the surroundings where only a few Padina pavonica stand out.

https://doi.org/10.1371/journal.pone.0017356.g004

The best-developed algal assemblage inside the cages at Kas included a canopy of Cystoseira spp. (mostly C. compressa); an understory of Dictyota spp., Hydroclathrus clathratus, and Padina pavonica; and a turf of small filamentous algae. Although the benthic communities observed were not bare-rock-barrens like those caused by sea urchin grazing, they were largely devoid of erect algae, and colonized by a microscopic carpet of diatoms and turf of filamentous algae. The algal assemblage outside the cages at the peak of the production period at all sites was limited to small Dictyota and Padina turfs.

Discussion

Our results show the most destructive effect of any alien marine fish in the Mediterranean marine ecosystem reported to date. The exclusion experiment clearly showed that without fish grazing, a well-developed algal assemblage would colonize the denuded habitats at the three study sites. We did not find sea urchins in our quadrats, and biomass of the two species of rabbitfish, Siganus luridus and S. rivulatus, was dominant. The massive recruitment of Siganus at the end of the experiment resulted in grazing inside the cages and the elimination of their algae within a month. The other herbivorous fish that may have an impact on the benthic algae is the parrotfish Sparisoma cretense, but its biomass was much lower than Siganus; and Sarpa salpa, which was not observed within our transects at the study sites. The carnivore sea bream Diplodus sargus can also consume moderate amounts of algae at our study habitat and depth (up to 10% of the weight of its stomach contents) [10]. However, this species does not reduce algal biomass dramatically elsewhere, even at the Medes Islands Marine Reserve, where its biomass is the largest in the Mediterranean, and more than 10 times larger than at our study sites [11].

These results suggest that an abundance of Siganus such as the observed (between 3 and 6 g m−2) may be sufficient to maintain benthic communities with extremely low algal biomass in the Mediterranean coast of Turkey. Sarpa salpa has been shown to maintain low algal cover in the NW Mediterranean [12], but not at the low levels encountered during this study.

Another question is whether Siganus can turn a well-developed algal assemblage into a barren, and how long it takes. We observed Siganus rivulatus, which recruited in massive numbers in September (Fig. 5), entering the cages and eating the algae, including large Fucales (Fig. 6), showing that Siganus have the potential to graze out well-developed algal canopies. Mediterranean algal assemblages exhibit seasonal changes in biomass, which typically declines after the ‘productive season’ (spring-summer) [13]. However, no infralittoral algal assemblage in the Mediterranean shows an abrupt decline to almost zero within a month [13] as we observed after Siganus grazing. Afterwards, the bottoms were devoid of visible algae and resembled a ‘true’ barren.

thumbnail
Figure 5. School of thousands of juvenile Siganus luridus at Kas, Turkey, after a massive recruitment event in September 2009.

https://doi.org/10.1371/journal.pone.0017356.g005

thumbnail
Figure 6. Experimental cages and surroundings, like this one at Kas, Turkey, were cleaned up by juvenile Siganus within a month.

https://doi.org/10.1371/journal.pone.0017356.g006

The grazing pressure needed to cause the shift from erect algae to ‘barren’ may be greater than that needed to maintain the barren. This difference has been well studied for the Mediterranean sea urchin Paracentrotus lividus [3] although we currently have no data for Siganus. Also, because of the absence of historical data on Siganus abundance and algal biomass on the Eastern Mediterranean, we cannot know when and why these barrens started to appear.

The two Siganus species consume the majority of macrophytes in the Eastern Mediterranean, although they prefer non-calcified algae and small filamentous algae, and have seasonal preferences [9]. However, they will eat whatever is available when algal biomass is lowest [14]. Why do Siganus stay on the barrens instead of moving to relatively close areas with larger algal biomass, and why they do not graze the uppermost sublittoral zone? Because Siganus have shown to be selective when macrophyte assemblages are diverse and abundant but they consume whatever is available in macroalgal-deprived bottoms [9], they may be maintaining microscopic carpets of filamentous algae and diatoms (‘gardening’ behavior).

Although we did not conduct a complete species list inside and outside the cages, we can assume that the loss of biodiversity due to fish grazing at the study sites is remarkable. Well-developed shallow water Mediterranean algal assemblages like those that grew inside the cages, dominated by a Cystoseira spp. canopy, can harbor up to 63–114 macroalgal species in an area of only 250–400 cm2 [3], [15]; whereas sea urchin barrens tend to have significantly fewer macroalgal species for the same area (as low as 23 species) [3].

The maximum biomass recorded in our cages was 625 g m−2 (wet mass) at Kas. Because that biomass arose from a baseline of less than 5 g m−2 in only 4 months, that maximum biomass is a conservative estimate of the potential annual primary production at Kas. These results suggest that the loss of primary production at the study habitat due to fish grazing may be considerable. However, we do not know the primary production provided by the small filamentous algae that Siganus appear to be cropping in the barrens (which can be relatively high in other habitats such as coral reefs). Siganus grazing should increase the turnover ratio in the depauperate barrens (i.e. the production/biomass ratio of the micro-turfs) but at the same time decrease total primary production. In any case, grazing causes a loss of biogenic structure that implies a loss of habitat for most marine invertebrates that live in algal canopies and that are the main prey items of the major carnivorous fishes on this habitat (Labridae, Sparidae and Serranidae) [10], [16], hence simplifying the food web. Siganus is directly transforming algae into faeces and shortcutting the complex Mediterranean food web at rocky infralittoral ecosystems [17], [18], [19].

The rapid growth of Cystoseira inside the cages was surprising because Cystoseira has relatively large zygots, and its propagule dispersal is thought to happen over very small distances (on the order of meters) [20]. First, there may have been small Cystoseira bases in small anfractuosities on the substrate, which had not been grazed by fish and could have grown the thalli we observed inside the cages. Second, propagules may have sunk from the wave-washed zone (upper infralittoral), where there was a narrow belt of Cystoseira. In any case, the rapid growth of Cystoseira suggests that recovery of algal assemblages is possible in the short term, should grazing pressure from Siganus be reduced.

Our results strongly suggest that grazing by the alien fish Siganus luridus and S. rivulatus creates and maintains areas denuded of erect algae in the Eastern Mediterranean, causing a dramatic reduction in biodiversity, biomass, and algal growth, with effects that may move up the food chain to the local fisheries. We hypothesize that a targeted experimental Siganus fishery in Turkey will help shift barrens to well-developed algal assemblages and enhance the recovery of the associated fauna. In the summer season, Lebanese fishermen collect the red alga Palisada sp. (quoted as Chondrophycus papillosus) (preferred by Siganus but largely unavailable to them in the field because the algae inhabit littoral Vermetid platforms) in large quantities and use it in traps as bait to capture specifically Siganidae [21]. Similar techniques could be used in Turkey to test whether the removal of the two alien marine fish leads to the restoration of the biogenic structure and biodiversity of Turkey's rocky coasts.

Methods

Study sites

The study was conducted at three sites on the Mediterranean coast of Turkey (Kas, Fethiye, and Bodrum) where we observed extensive barrens without sea urchins (Fig. 2). Sampling was conducted at an average depth of 10 m (±2 m) on rocky substrates with sub-horizontal slopes.

Fish abundance

Fish data were collected by using standard underwater visual census at six stations at each site, separated at least 1 km apart from the next, in May 2009. We conducted 3 replicate 25 m-long and 5 m-wide transects at each station. Along each transect, the diver swam one way at constant speed, identifying and recording the number and size of each fish encountered [22]. Fish sizes were estimated visually in 5 cm increments of total length (TL). Fish biomass (wet weight) was estimated from size data by means of length-weight relationships from the available literature and existing databases [23].

For our analysis, we assigned each fish taxon to one of 4 trophic groups using the information about diet in the literature [23], and in previous Mediterranean studies [24]: apex predators, carnivores, herbivores, and (zoo)planktivores. To test for differences in biomass between trophic groups within each site, we performed a 2-way ANOVA, with site and station as random factors, and station nested within site.

Fish exclusion experiment

To test whether the exclusion of fish grazing results in algal growth we conducted caging experiments at the three sites with extensive barrens that had no sea urchins (Kas, Fethiye, and Bodrum). We ran the experiments between March and November 2009 at Bodrum, but cages unexpectedly disappeared in August at Fethiye and in September at Kas. We installed twelve 60×40×25 cm plastic cages with mesh 2.5 cm in size. Potential caging artifacts include reduction of irradiance and water flow by the cages (which could inhibit algal growth inside the cages). Sala and Boudouresque experimentally found that this type of plastic cage does not significantly reduce irradiance of water flow, hence the absence of a control for caging artifacts in our study [11].

Once a month, we lifted the cages and photographed cages and an equal number of nearby control quadrats using a digital camera installed on a quadrapod. We measured the cover of algal taxa in the lab using Photogrid, and calculated algal biomass using the relationship between cover and biomass in the literature [13] and our own samples on nearby sites to account for the increase in biomass with height for the larger algae. The biomass of crustose coralline algae was not measured because they were not observable on the photographs when the canopy algae were present. In addition, we conducted sea urchin counts by placing fifty 50×50 cm quadrats haphazardly within 50 m of the enclosures at each site.

To test for differences in algal biomass between enclosures and control plots over time (between April and August) we performed a 3-way ANOVA, with time, treatment (cage vs. control), and site (Fethiye, Kas, Bodrum) as independent variables.

Acknowledgments

We are grateful to the Turkish Ministry of Foreign Affairs for the research permit, to Harun Güçlüsoy and Mustafa Koç for help in the field, and to two anonymous reviewers for constructive comments that improved an earlier version of the manuscript.

Author Contributions

Conceived and designed the experiments: ES EB ZK. Performed the experiments: ES EB DY ZK. Analyzed the data: ES EB. Wrote the paper: ES EB.

References

  1. 1. Coll M, Piroddi C, Steenbeek J, Kaschner K, Ben Rais Lasram F, et al. (2010) The biodiversity of the Mediterranean Sea: estimates, patterns and threats. PLoS One 5(8): e11842.
  2. 2. Sala E, Boudouresque CF, Harmelin-Vivien M (1998) Fishing, trophic cascades, and the structure of algal assemblages: evaluation of an old but untested paradigm. Oikos 82: 425–439.
  3. 3. Verlaque M (1987) Relations entre Paracentrotus lividus (Lamarck) et le phytobenthos de Méditerranée occidentale. In: Boudouresque CF, editor. Colloque international sur Paracentrotus lividus et les oursins comestibles. Marseille: GIS Posidonie Publ. pp. 5–36.
  4. 4. Guidetti P, Dulcic J (2007) Relationships among predatory fish, sea urchins and barrrens in Mediterranean rocky reefs across a latitudinal gradient. Marine Environmental Research 63: 168–184.
  5. 5. Tortonese E (1970) On the ocurrence of Siganus (Pisces) along the coast of North-Africa. Doriana 4: 1–2.
  6. 6. Ben Tuvia A (1964) Two siganid fishes of Red Sea origin in the eastern Mediterranean. Bull Sea Fish Res St Haifa 37: 3–9.
  7. 7. Golani D, Orsi-Relini L, Massuti E, Quignard JP (2010) CIESM Atlas of exotic species in the Mediterranean. Vol. 1 - Fishes. http://www.ciesm.org/atlas/appendix1.html.
  8. 8. Daniel B, Piro S, Charbonnel E, Francour P, Letourneur Y (2009) Lessepsian rabbitfish Siganus luridus reached the French Mediterranean coasts. Cybium 33: 163–164.
  9. 9. Bariche M (2006) Diet of the Lessepsian fishes, Siganus rivulatus and S. luridus (Siganidae) in the eastern Mediterranean: A bibliographic analysis. Cybium 30: 41–49.
  10. 10. Sala E, Ballesteros E (1997) Partitioning of space and food resources by three fish of the genus Diplodus (Sparidae) in a Mediterranean rocky infralittoral ecosystem. Marine Ecology Progress Series 152: 273–283.
  11. 11. Sala E, Boudouresque CF (1997) The role of fishes in the organization of a Mediterranean sublittoral community. I: Algal communities. Journal of Experimental Marine Biology and Ecology 212: 25–44.
  12. 12. Ruitton S, Francour P, Boudouresque CF (2001) Relationships between algae, benthic herbivorous invertebrates and fishes in rocky sublittoral communities of a temperate sea (Mediterranean). Estuarine, Coastal and Shelf Science 50: 217–230.
  13. 13. Ballesteros E (1992) Els vegetals i la zonació litoral: espècies, comunitats i factors que influeixen en la seva distribució. Barcelona: Institut d'Estudis Catalans.
  14. 14. Lundberg B, Ogorek R, Galil B, Goren M (1999) Algal food of Siganid fishes in Shiqmona, Israel. Israel Journal of Zoology 45: 314.
  15. 15. Ballesteros E (1990) Structure and dynamics of the Cystoseira caespitosa Sauvageau (Fucales, Phaeophyceae) community in the North-Western Mediterranean. Scientia Marina 54: 155–168.
  16. 16. Reñones O, Polunin N, Goñi R (2002) Size-related dietary shifts of Epinephelus marginatus in a western Mediterranean littoral ecosystem: an isotope and stomach content analysis. Journal of Fish Biology 61: 122–137.
  17. 17. Deudero S, Pinnegar J, Polunin N, Morey G, Morales-Nin B (2004) Spatial variation and ontogenic shifts in the isotopic composition of Mediterranean littoral fishes. Marine Biology 145: 971–981.
  18. 18. Jennings S, Reñones O, Morales-Nin B, Polunin N, Moranta J, et al. (1997) Spatial variation in the 15N and 13C stable isotope composition of plants, invertebrates and fishes on Mediterranean reefs: implications for study of trophic pathways. Marine Ecology Progress Series 146: 109–111.
  19. 19. Pinnegar J, Polunin N (2000) Contributions of stable-isotope data to elucidating food webs of Mediterranean rocky infralittoral fishes. Oecologia 122: 399–409.
  20. 20. Soltan D, Verlaque M, Boudouresque CF, Francour P (2001) Changes in macroalgal communities in the vicinity of a Mediterranean sewage outfall after the setting up of a treatment plant. Marine Pollution Bulletin 42: 59–70.
  21. 21. Bariche M (2002) Biologie et ecologie de deux especes lessepsiennes (Siganus rivulatus et Siganus luridus, Téléostéens, Siganidae) sur les côtes du Liban. These de Doctorat, 223 p. Universite de la Mediterranee, Marseille.
  22. 22. Harmelin-Vivien ML, Harmelin JG, Chauvet C, Duval C, Galzin R, et al. (1985) Évaluation des peuplements et populations de poissons. Méthodes et problèmes. Rev Ecol Terre & Vie 40: 467–539.
  23. 23. Froese R, Pauly D (2010) FishBase. World Wide Web electronic publication. www.fishbase.org.
  24. 24. Guidetti P, Sala E (2007) Community-wide effects of marine reserves in the Mediterranean Sea. Marine Ecology Progress Series 335: 43–56.