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Open Access Research article

Competition between the invasive macrophyte Caulerpa taxifolia and the seagrass Posidonia oceanica: contrasting strategies

Gérard Pergent1*, Charles-François Boudouresque2, Olivier Dumay1, Christine Pergent-Martini1 and Sandy Wyllie-Echeverria3

Author Affiliations

1 UMR CNRS SPE 6134, University of Corsica, Faculty of Sciences, BP 52, 20250 Corte, France

2 UMR CNRS DIMAR, University campus of Luminy, 13288 Marseilles cedex 9, France

3 University of Washington, UW Botanic Gardens, Center for Urban Horticulture, Box 354115, Seattle, WA 98195, USA

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BMC Ecology 2008, 8:20  doi:10.1186/1472-6785-8-20

The electronic version of this article is the complete one and can be found online at:

Received:6 September 2007
Accepted:11 December 2008
Published:11 December 2008

© 2008 Pergent et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.



Plant defense strategy is usually a result of trade-offs between growth and differentiation (i.e. Optimal Defense Theory – ODT, Growth Differentiation Balance hypothesis – GDB, Plant Apparency Theory – PAT). Interaction between the introduced green alga Caulerpa taxifolia and the endemic seagrass Posidonia oceanica in the Mediterranean Sea offers the opportunity to investigate the plausibility of these theories. We have accordingly investigated defense metabolite content and growth year-round, on the basis of an interaction gradient.


When in competition with P. oceanica, C. taxifolia exhibits increased frond length and decreased Caulerpenyne – CYN content (major terpene compound). In contrast, the length of P. oceanica leaves decreases when in competition with C. taxifolia. However, the turnover is faster, resulting in a reduction of leaf longevity and an increase on the number of leaves produced per year. The primary production is therefore enhanced by the presence of C. taxifolia. While the overall concentration of phenolic compounds does not decline, there is an increase in some phenolic compounds (including ferulic acid and a methyl 12-acetoxyricinoleate) and the density of tannin cells.


Interference between these two species determines the reaction of both, confirming that they compete for space and/or resources. C. taxifolia invests in growth rather than in chemical defense, more or less matching the assumptions of the ODT and/or PAT theories. In contrast, P. oceanica apparently invests in defense rather than growth, as predicted by the GDB hypothesis. However, on the basis of closer scrutiny of our results, the possibility that P. oceanica is successful in finding a compromise between more growth and more defense cannot be ruled out.


Several theories have been advanced to explain the chemical pathways and tissue differentiation strategies that have evolved to reduce the effect of competition between different individuals of different species. Common theories proposed to explain defense strategies in plants are: Optimal Defense Theory (ODT) [1]; the Growth-Differentiation Balance Hypothesis (GDBH) [2]; the Resource Availability Theory (RAT) [3] and the Plant Apparency Theory (PAT) [4]. ODT predicts that plants should have the highest defense levels in parts that have the highest value in terms of fitness. GDBH predicts that defense allocation will be a result of trade-offs between growth (increasing plant size) and defense (or tissue differentiation); as long as all environmental factors are favorable for growth, growth processes predominate over differentiation [2]. According to RAT plants with abundant resources invest in growth rather than defense. Finally PAT is based on the observation that both types of strategy (growth and defense) occur in plants but that they differ in cost.

ODT arises from cost assumptions identified by PAT, that is that defenses are costly in terms of fitness. A further consequence is that environmentally stressed plants should be less well defended against herbivores, and therefore more palatable, than unstressed plants, as they have fewer resources available for defense [5]. Clearly, ODT-PAT assumptions (when plants are stressed, they invest in growth rather than defense) may seem incongruent with GDB-RAT assumptions (when resources are scarce, plants invest in defense rather than growth).

Patterns of plant defense and resource allocation as a function of stress, disturbance and herbivore pressure have given rise to a considerable body of literature, especially in the terrestrial realm (e.g. [2,6,5,11]). However, marine models have been relatively poorly investigated [12-15].

Interaction between the green alga C. taxifolia (Vahl) C. Agardh introduced into the Mediterranean Sea [16] and the endemic seagrass P. oceanica (Linnaeus) Delile offers the opportunity to investigate the reliability, incongruence and/or complementarity of the theories comparing defense, growth and competition. In addition, both species produce defense compounds (terpenes and phenolic acids, respectively; [17-19]) in such a way that interactions can be isolated and investigated. Here, we investigate defense strategies at the molecular level by evaluating the production of defense compounds (phenolic compounds in P. oceanica and Caulerpenyne (CYN) in C. taxifolia) and the influence of this production on growth over an annual growth cycle. To this end, we identified an interaction gradient, i.e. isolated populations and co-occurring populations and examined the effect of interaction on the two species. The purpose of this paper is to determine whether the fitness of either plant is compromised in the presence of the other; and if fitness is indeed compromised, whether a pattern of defense may be identified.


Leaf and frond length

P. oceanica shoots exhibited seasonal variation in the mean number (Fig. 1) and mean length of leaves (Fig. 2). The length of both adult (752.3 ± 43.1 mm for L0 and 509.7 ± 55.3 for L3) and intermediate leaves (Fig. 2) decreased significantly when the level of interaction with C. taxifolia increased (ANOVA; F = 40.1, df = 2, P < 0.001; F = 54.8, df = 2, P < 0.001, respectively). As a result, the biomass of P. oceanica shoots decreased from L0 (no interaction) through L2 (high interaction); for instance in May 1999, biomass is respectively, 125.3 ± 16.5, 84.6 ± 10.4 and 67.5 ± 9.4 mg dry weight, for L0, L1 and L2 (54.5, 47.8 and 38.1 g dry weight per m2). Similarly, the mean frond length of C. taxifolia changed seasonally (Fig. 3) but in the opposite direction from P. oceanica : the length significantly increased with the level of interaction (ANOVA; F = 89.9, df = 2, P < 0.001).

thumbnailFigure 1. Leaf number. Mean number of intermediate and adult leaves of Posidonia oceanica according to the period and the level of interaction with Caulerpa taxifolia. Bars: Confidence level 95%, n = 30 shoots.

thumbnailFigure 2. Leaf length. Mean length of intermediate leaves of Posidonia oceanica according to the period and the level of interaction with Caulerpa taxifolia. Bars: Confidence level 95%, n = 30 shoots.

thumbnailFigure 3. Frond length. Mean length of Caulerpa taxifolia fronds according to the period and the level of interaction with Posidonia oceanica. Bars: Confidence level 95%, n = 40 fronds.

Leaf renewal and primary production of Posidonia oceanica

The number of P. oceanica leaves formed during a one-year period increased with the level of interaction (Fig. 4) while the mean life-span of leaves decreased significantly (Fig. 5; ANOVA; F = 14.4, df = 2, P < 0.001). The increase in the number of leaves produced during the study period generated an increase in the net primary production dedicated to leaf blades and sheaths (Fig. 6), with an 82% increase observed between L0 (no interaction) and L2 (highest interaction) (see Additional file 1).

Additional File 1. Table 1 – Levels of interaction. Description of the three levels of interaction between C. taxifolia and P. oceanica.

Format: DOC Size: 32KB Download file

This file can be viewed with: Microsoft Word ViewerOpen Data

thumbnailFigure 4. Leaf production. Mean number of Posidonia oceanica leaves produced per shoot during the year of study according to the level of interaction with Caulerpa taxifolia. Bars: Confidence level 95%, n = 30 shoots.

thumbnailFigure 5. Leaf life-span. Mean life-span of Posidonia oceanica leaves, according to the level of interaction with Caulerpa taxifolia. Bars: Confidence level 95%, n = 5 (L0) n = 7 (L1), n = 10 (L2).

thumbnailFigure 6. Posidonia primary productionr. Net primary production (in g dry weight shoot-1 yr-1) of Posidonia oceanica dedicated to rhizomes, sheaths and blades, according to the level of interaction with Caulerpa taxifolia. The method of estimation (see [21] Pergent and Pergent-Martini, 1991) does not allow calculation of a confidence interval.

Tannin cells in Posidonia oceanica leaves

The density of tannin cells varied significantly along P. oceanica adult leaf, with a peak in the central part of the leave (Fig. 7; ANOVA; F = 3.5, df = 7, P < 0.05). A significant increase in the density of tannin cells in blades was apparent with increasing levels of interaction with C. taxifolia (ANOVA; F = 29.3, df = 2, P < 0.001). For example, at 100 mm above the base of the leaf, the mean density was 16.7 ± 10.6 cells cm-2 (L0), 31.1 ± 15.5 (L1) and 57.8 ± 21.2 (L2).

thumbnailFigure 7. Tanin cells. Change in the mean density of tannin cells along the length of Posidonia oceanica adult leaves (sheaths and blades) as a function of the level of interaction with Caulerpa taxifolia. Distance along the leaf was measured below and above the limit between sheath and blade. For each adult leaf of each shoot several replicates were performed; the total number of replicates was n = 78 (L0) n = 89 (L1), n = 83 (L2). Bars: Confidence level 95%,.

Phenolic compounds of Posidonia oceanica leaves

Five major phenolic compounds were identified; 4-hydroxybenzoic acid, 4-coumaric acid, trans-cinnamic acid, caffeic acid and a mixture (hereafter P1) of at least two compounds, one of which is ferulic acid. Among minor phenolic compounds, the methyl 12-acetoxyricinoleate (hereafter P2) presented changes with the level of interaction (see below).

No clear seasonal trend was evident over time in the total phenolic content of P. oceanica leaves (data not presented). There is a weak but not significant (ANOVA; F = 2.7, df = 2, P = 0.07) increase in mean total phenolic content between L0 (297 ± 65 μg g dry weight-1) and L2 (357 ± 100). Conversely, P1 and P2 exhibited a significant increase with the level of interaction with C. taxifolia (Fig. 8; ANOVA; respectively F = 8.6, df = 2, P= 0.0009; F = 5.4, df = 2, P= 0.0091).

thumbnailFigure 8. Phenolic compounds. Mean annual content in P1 (a mixture with ferulic acid) and P2 (methyl 12-acetoxyricinoleate) phenolic compounds in adult leaves of Posidonia oceanica, as a function of the level of interaction with Caulerpa taxifolia. Bars: Confidence level 95%, n = 17 (L0) n = 18 (L1), n = 18 (L2).

Caulerpenyne (CYN) content in Caulerpa taxifolia fronds

CYN content of C. taxifolia fronds varied seasonally (Kruskal-Wallis test; p < 0.01), with a maximum in summer and a minimum in spring (Fig. 9). Whatever the season, CYN content varied as a function of the level of interaction with P. oceanica (Kruskal-Wallis test; p < 0.01); in July, for instance, CYN values were 3.7 ± 0.7 mg CYN g wet weight-1 (L0), 2.0 ± 0.8 (L1) and 1.4 ± 0.6 (L2).

thumbnailFigure 9. Caulerpenyne content. Caulerpenyne (CYN) content (in mg CYN g wet weight-1) in Caulerpa taxifolia fronds as a function of both season and level of interaction with Posidonia oceanica. Bars: Confidence level 95%, n = 5.


Caulerpa taxifolia strategy

When in competition with P. oceanica, C. taxifolia exhibitsincreased frond length (growth) and decreased CYN content (tissue differentiation). This may be influenced by the low levels of irradiance observed beneath the P. oceanica canopy (e.g., [20,21]). Increased growth is often linked to light availability. A similar competition type (for resources; see [22]) was also observed in another invasive species, Sargassum muticum (Yendo) Fensholt [23]. Clearly, the response of C. taxifolia to competition is to invest in growth rather than defense. However, it is worth noting that increased frond length does not necessarily imply an increase in primary production, because longer fronds may be slender.

Though terpenes should be considered as rather low cost defense metabolites [4,24], they do appear to be too costly for C. taxifolia, since the plant reaction is to lower CYN concentration. In general, terpene production, mainly CYN, defends C. taxifolia against herbivory [25,17-19,26] but is also essential for the wound closure of the cells [27]. For example C. taxifolia is avoided by herbivorous sea-urchins (Paracentrotus lividus) and fish (Sarpa salpa) [28-30]. According to [31], C. taxifolia is less palatable to sea-urchins than P. oceanica in summer, when the terpene content is maximum, whereas the reverse occurs in winter. Being more palatable when co-existing with P. oceanica, C. taxifolia couldactually be grazed more frequently. However, no conspicuous herbivore bites were observed at any time during field work. Conversely when compared with winter and spring values, the level of chemical defense in C. taxifolia remains relatively high in summer (Fig. 9).

We confirmed observations by [32] and [19] with the finding that the annual cycle of CYN content exhibits dramatic changes between high summer and autumn values and relatively low winter and spring concentration (Fig. 9). This cycle is coupled with the growing season of C. taxifolia [33]. Our finding that the actively growing summer fronds of C. taxifolia could be more strongly chemically defended than decaying winter fronds illustrates ODT [1].

Posidonia oceanica strategy

In contrast with C. taxifolia, the length of P. oceanica leaves decreases when in competition with C. taxifolia (Fig. 2). However, the leaf turn-over is faster, resulting in a reduction of leaf longevity and an increase in the number of leaves produced per year. The primary production of P. oceanica is therefore enhanced by the presence of C. taxifolia (Fig. 6). [34] also observed the reduction of leaf longevity; however leaf length was either increased (adult leaves) or reduced (intermediate leaves).

As far as the production of defense metabolites is concerned, the P. oceanica strategy also differs from that of C. taxifolia. Firstly, the overall concentration of phenolic compounds does not decline. Secondly, some phenolic compounds (including ferulic acid and a methyl 12-acetoxyricinoleate) display an increase. Third, the density of tannin cells, which are specialized in the synthesis of the phenolic compounds [35,36] increases (supporting earlier findings by [34] and [37]). While terpenes are recognized mostly in anti-herbivore interactions, phenolic compounds are supposed to be involved in defense against pathogens and allelopathy by reducing the growth of competing plants [38-41]. Nevertheless, C. taxifolia appears not affected by the increase of these phenolic compounds.

Though superficial interpretation of our results could lead to the conclusion than P. oceanica invests in defense rather than growth (since biomass declines), it appears that it in fact invests both in defense and growth (since primary production actually increases).

Another explanation for this energy imbalance may relate to the structure of the P. oceanica meadow and the production of below ground rhizomes. These rhizomes constitute a storage organ for nutrients and polysaccharids [42-44], as well as a route for the transfer of photosynthate between shoots [45,46]. However, the translocation hypothesis would only work for site L1, with photosynthates possibly provided by shoots located in the inner meadow. As far as site L2 is concerned, the surface area of the meadow colonized by C. taxifolia is much larger than the maximum distance of translocation (a few tens of centimetres), which could invalidate the hypothesis.


Like many invasive species, C. taxifolia is able to quickly colonize open areas and synthesize defense metabolites, namely terpene compounds, that are cheap to produce but with high turnover rates [33]. Conversely, P. oceanica grows very slowly [47], is a late successional species [48] and synthesizes defense phenolic compounds, that are costly to produce but more economical over time.

Interference between these two species determines the reaction of both (Fig. 10), which demonstrates that they compete for space and/or resources. C. taxifolia invests in growth rather than in chemical defense, more or less matching the assumptions of ODT and/or PAT. It is worth noting that the terpenes this plant produces are efficient against herbivores, but probably inefficient against competition with other plants, due to low water-solubility and rapid degradation in sea water [19,49]. Though investing in growth, C. taxifolia fronds are unable to grow taller than P. oceanica leaves (Fig. 2 and 3). This suggests that, at this study site, C. taxifola cannot successfully compete with P. oceanica for light. In contrast, P. oceanica apparently invests in defense rather than growth, as predicted by the GDB hypothesis [2]. However, we cannot rule out the possibility that P. oceanica may be successful in combining growth and defense.

thumbnailFigure 10. Energy allocation and strategy. Different energy allocations and competition strategy between Posidonia oceanica (high left) and Caulerpa taxifolia (down right). (E⇗): Increase in energy needs; (E⇘): Decrease in energy needs.


Study Site

Three adjacent sites (around 10 000 m2 each), situated in the subtidal region at Cap Martin (French Riviera) from 9 to 11 m, presenting similar environmental conditions (substrate, exposure, depth), were sampled every two months, from May 1999 to July 2000 using SCUBA diving. Three levels of interaction between C. taxifolia and P. oceanica were identified and replicate sampling was performed in each interaction category (Additional file 1). Formation of the P. oceanica meadow primarily resulted from the growth of orthotropic (erect) shoots. No seedling recruitment was observed during the course of the study. Shoot density differences were not significant between monospecific stands L0 (435 ± 64 shoots.m-2) and locations with co-occurring populations of P. oceanica and C. taxifolia fronds (565 ± 158). The density of C. taxifolia fronds was also similar. Within each site we collected randomly 30 individual sterile adult shoots of P. oceanica with intact rhizomes and 40 fronds of C. taxifolia connected to different stolons.

Sample Processing of individual shoots and fronds

Leaf lengths were measured and the number of adult (oldest external leaves with a sheath) and intermediate leaves (younger internal leaves without sheath) was recorded according to Giraud' method [50]. Dry weights for leaf blades and leaf sheaths were computed separately. Lepidochronological analysis was also carried out to establish the average cycle of leaf renewal and estimate the annual production of leaves and rhizomes [51]. In this method, the mean leaf primary production corresponds to the mean number of leaves produced per shoot and per year multiplied by sheath and blade biomass. The length of C. taxifolia fronds was measured to the nearest millimeter.

Tannin cells analysis

In September 1999, a sub-sample of three shoots of P. oceanica was preserved in ethanol (ethanol – 95%), to observe tannin cells. Once rinsed with fresh water, transverse sections (50 μm thick) were performed along the adult leaves at 2 cm intervals (sheath) and 5 cm intervals (blade). Tannin cells were then counted using optical transmission microscopy, enlargement ×100 and density expressed as a number of cells cm2.

Preparation and chromatographic analysis of phenolic compounds

P. oceanica shoots were kept at low temperatures (1–5°C) during transport. In the laboratory, leaf epiphytes were removed using a razor blade and leaves were freeze dried for 72 hours (HETO®, Lab Equipment-FD4). Extraction of phenolic compounds was then initiated [52,38]. 1 to 3 g dry weight of leaf tissues were infused for 3 h in 200 ml of aqueous ethanol (1:1), in darkness (40°C). Extraction was carried out with ethyl acetate after vacuum evaporation of the ethanol, at 45°C. The organic phase was thus separated in the separatory funnel, dried using anhydrous sodium sulphate, and then evaporated until a dry residue was obtained. The liposoluble phenolic compounds extracted were stabilized by conversion of the hydroxyl groups into trimethylsilyl groups and the dry extract was added to 50 μl of the mixture trimethylchlorosilane: hexamethyldisilazane: pyridine (1:3:9), 100 μl of bis(trimethylsilyl)trifluoroacetamide and 1.5 μl of trimethylchlorosilane and heated at 70°C for 30 minutes in an inert atmosphere.

For each interaction level, three stabilized samples were analysed by GC and by GC-MS. The GC analyses were carried out using a Perkin-Elmer Autosystem GC apparatus equipped with FID detectors and fused-silica capillary column (30 m × 0.25 mm i.d., film thickness 0.25 μm), Rtx-1 (dimethyl polysiloxane). Oven temperature was programmed to increase the temperature environment by 2°C/m increments between 60°C to 230°C and then hold temperature at 230°C for 35 min. Injector and detector temperatures were maintained at 280°C. Samples were injected in the split mode (1:80), using helium as a carrier gas (1 ml/min).

The GC-MS analyses were performed on a Perkin-Elmer quadrupole MS system (model Q-mass 910). MS conditions occurred as follows: ionisation voltage of 70 eV, scan rate 1 scan/s, mass range 35–350 Da, ion source temperature 200°C. The spectrometer was directly coupled to a Perkin-Elmer Autosystem GC. A fused-silica capillary column (30 m × 0.25 mm i.d., film thickness 0.25 μm), Rtx-1 (dimethyl polysiloxane) was employed. The temperature conditions and the carrier gas were the same as above.

Compound identification was based on: (i) comparison between retention times on an apolar column, and those of standards injected beforehand, and (ii) computer matching with commercial mass spectra libraries [53]. A standard curve derived from pure products enabled the concentrations of phenolic compounds in the samples to be quantified.

Preparation and chromatographic analysis of Caulerpenyne (CYN)

Five samples of C. taxifolia were taken from each experimental site. Algal fronds were processed by rinsing in fresh water, storing at -20°C in MeOH at a concentration of 5 g wet weight of each frond in 50 ml of MeOH (MeOH, 95–98%, Chromanorm; HPLC quality), in order to avoid any degradation of the CYN. Extraction of CYN, the major terpene compound produced by C. taxifolia [19], was performed directly in the MeOH. To ensure the total diffusion of the CYN present within each frond, samples were sonicated for five minutes. CYN measurements were performed using High Performance Liquid Chromatography. Thus, 10 μl of each sample was injected into the glass column of 5 μm silica (100 × 3 mm, Chrompack) and eluted with a MeOH – water solvent mixture (8:2) at a speed of 0.5 ml min-1. As the retention time of CYN is of the order of 2.8 min, the injection time for each sample was set at 6 min. Measurements were performed at a UV wavelength of 254 nm, sensitivity = 0.32. The HPLC pump (Waters 600), equipped with an automatic injector (Waters 717), was monitored using specially-designed software (Millennium Waters software), that also controlled the PAD data acquisition (Photodiode Array Detector Waters 996). This system enables CYN peaks to be identified during elution both in real time and under the measurement conditions. Three replicates were performed for each sample to assess the analytical dispersion. The standard curve, established on the basis of purified CYN, allowed determination of CYN levels in the samples. A direct relationship between HPLC peaks and CYN levels was obtained.


After checking for normality (Shapiro-Wilks test) and homogeneity of the variances (Bartlett's test), analysis of variance (ANOVA) was carried out using Statgraphic v.3.0 software. The factors were represented by season, the station and tissue type (adult sheaths and blades and intermediate leaves) and in the case of tannin cells, by the position of the section on the leaf. These ANOVA were then completed by a Tukey's multiple range test, in order to locate the differences. It should be noted that because of the small sample size for the study of the phenolic compounds (n = 3), the normality of the data could not be determined. However, ANOVA is a robust test under the conditions of application [54]. For each test, the null hypothesis was rejected with a probability of 95%.

Authors' contributions

GP director of thesis (OD), co-written the paper with CFB, participated to field mission. CFB co-written the paper. OD carried out field mission and analysis. CPM responsible of the program. SWE participated to the redaction and corrected the manuscript.

All authors read and approved the final manuscript


This study was made possible by a University cooperation program supported by the European Communities Commission (INTERREG Corsica Tuscany) and by a scientific research program financed by the French Ministry of the Environment.


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