Abstract
In the Mediterranean Sea, the fleshy red alga Phyllophora crispa forms dense mats of up to 15 cm thickness, mainly located on rocky substrates in water depths below 20 m. Because of the observed density of these mats and some first observations, we hypothesize that P. crispa is a yet undescribed ecosystem engineer that provides a multitude of ecological niches for associated organisms along small-scale environmental gradients. Therefore, we conducted an in-situ pilot study in the Western Mediterranean Sea to assess potential influence of the algae mats on the key environmental factors water movement, temperature and light intensity. We comparatively and simultaneously measured in P. crispa mats, in neighboring Posidonia oceanica seagrass meadows, on neighboring bare rocky substrates without algae mats, and in the directly overlying water column. We used several underwater logging sensors and gypsum clod cards. Findings revealed that P. crispa significantly reduced water movement by 41% compared to the overlying water column, whereas water movement was not affected by P. oceanica meadows and bare rocky substrates. Surprisingly, P. crispa increased the water temperature by 0.3°C relative to the water column, while the water temperature in P. oceanica and on bare rocky substrates was reduced by 0.5°C. Light intensity inside the red algae mats was reduced significantly by 69% compared to the water column. This was similar to measured light reduction of 77% by P. oceanica. These findings highlight the strong influence of the dense red algae mats on some key environmental factors. Their influence is obviously similar or even higher than for the well-known seagrass ecosystem engineer. This may be a factor that facilitates associated biodiversity similarly as described for P. oceanica.
Highlights
Ecosystem engineers are defined as organisms that control the availability of resources either directly or indirectly by their ability to change the physical state of abiotic or biotic material (Jones et al, 1994, 1997)
Results show a reduction in weight loss of gypsum clod cards relative to the water column by 41 ± 8% in P. crispa mats, 25 ± 16% in Posidonia oceanica seagrass meadows, and 13 ± 8% on the rocky substrates (Figure 1)
We investigated the influence of P. crispa on the environmental factors water movement, temperature and light intensity
Summary
Ecosystem engineers are defined as organisms that control the availability of resources either directly or indirectly by their ability to change the physical state of abiotic or biotic material (Jones et al, 1994, 1997). The metabolism of both corals and their symbiotic algae (i.e., respiration and photosynthesis) cause oxygen micro-gradients near reefs (Shashar et al, 1993) that can affect a range of associated species (Vogel, 1981; Atkinson, 1992). Mangroves are another example of structural ecosystem engineers that create habitat for numerous aquatic species (Robertson and Blaber, 1992; Kandasamy and Bingham, 2001). Aggregations of such macroalgae form a unique habitat for marine organisms (Christie et al, 2003) by dampening water currents (Jackson, 1997; Gaylord et al, 2007) and diminishing light (Pearse and Hines, 1979; Reed and Foster, 1984; Stewart et al, 2008)
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