Phytoplankton grazing by epi- and infauna inhabiting exposed rocks in coral reefs

Exposed rocks with no visible macro-fauna are abundant in all coral reefs. Depletion of phytoplankton cells and pigments by the minute crypto fauna inhabiting the outer few centimeters of such rocks was experimentally studied over an annual cycle in the Gulf of Aqaba, Red Sea. Different substrata were introduced into small (3.6 L), well mixed, tanks that were fed by running seawater pumped directly from the reef at a rate of 11±1 L h⁻¹. A steady-state reduction in phytoplankton abundance and chlorophyll a concentration of 38±26% (mean ± 1 SD) was found for untreated rocks but not for sand, gravel, or killed controls. Average areal clearance rate by untreated rocks was 17.3±8.0 ml cm⁻² h⁻¹. Conservative extrapolation of this rate to the whole reef community suggests that the fauna inhabiting exposed rocks clears 2.1±0.9 m³ m⁻² d⁻¹ at Eilat. Phytoplankton removal by untreated rocks varied from 1.5 ng chlorophyll a cm⁻² h⁻¹ during the oligotrophic summer conditions to 6 ng chlorophyll a cm⁻² h⁻¹ during the spring bloom. These values correspond to a potential nitrogen gain of 1.3 and 5.2 mmol N m⁻² day⁻¹, respectively. Cryptic reef-rock fauna can have a key role in the biogeochemical functioning of coral reef communities.     

Food web structure in exotic and native mangroves: a Hawaii–Puerto Rico comparison

Plant invasions can fundamentally alter detrital inputs and the structure of detritus-based food webs. We examined the detrital pathways in mangrove food webs in native (Puerto Rican) and introduced (Hawaiian) Rhizophora mangle forests using a dual isotope approach and a mixing model. Based on trophic-level fractionation of 0–1‰ for δ ¹³C and 2–3‰ for δ ¹⁵N, among the invertebrates, only nematodes, oligochaetes, and nereid polychaetes from native mangroves exhibited stable isotopes consistent with a mangrove-derived diet. Certain fauna, in particular tubificid oligochaetes, had δ ¹³C values consistent with the consumption of mangrove leaves, but they were depleted in ¹⁵N, suggesting their primary nitrogen source was low in ¹⁵N, and was possibly N₂-fixing bacteria. In introduced mangroves, all feeding groups appeared to rely heavily on non-mangrove sources, especially phytoplankton inputs. Mixing model results and discriminant analysis showed clear separation of introduced and native mangrove sites based on differential food source utilization within feeding groups, with stronger and more diverse use of benthic foods observed in native forests. Observed differences between native and invasive mangrove food webs may be due to Hawaiian detritivores being poorly adapted to utilizing the tannin-rich, nitrogen-poor mangrove detritus. In addition, differential utilization of mangrove detritus between native and introduced mangroves may be a consequence of forest age. We postulate that increasing mangrove forest age may promote diversification of bacterial food webs important in N and S cycling. Our results also suggest a potentially important role for sulfur bacteria in supporting the most abundant infaunal consumers, nematodes, in the most mature systems. Electronic supplementary material The online version of this article (doi:) contains supplementary material that is available to authorized users.     

Patches of barnacles and ascidians in soft bottoms: Associated motile fauna in relation to the surrounding assemblage

Epibenthic patches dominated by barnacles Balanus crenatus Bruguiere and solitary ascidians Styela spp., Bolthenia echinata (L.) and Molgula spp. in the White Sea shallow subtidal develop on bivalve shells and small stones surrounded with muddy sand. The space between barnacles and ascidians is filled with muddy sediment inhabited by motile taxa. We hypothesized that (i) epibenthic patches and unstructured sediment would attract different motile fauna and (ii) motile fauna of the patches would be affected by local abundances of epibenthic foundation species. Most dominant motile species demonstrated a significant difference in abundance between the two microhabitats. In contrast to the fauna of the sediment, species composition observed in aggregations of barnacles and ascidians was stable across different locations. In the field experiment initially clear bivalve shells after 5 years of exposure developed barnacle clusters with motile fauna similar to that observed in natural aggregations. Amphipods, isopods and bivalves, capitellid polychaets, Cirratulus cirratus (Müller) and Pholoe minuta Fabricius (Polychaeta) dominated in the sediment inside epibenthic patches. The proportion of capitellids, known to be sensitive to organic enrichment, was much higher within the patches than outside. The abundances of motile taxa found in aggregations were mostly determined by the number of barnacles of different size and of their empty shells, the biomass of ascidians, and the effect of location. Different dominant species demonstrated sensitivity to different parameters.Physical structure of the habitat, provided by barnacles and ascidians, as well as their biodeposition activity are regarded as the main factors structuring the motile fauna in the community studied. The spatial pattern observed seems to imply a range of pattern-generating biogenic processes, similar to those previously revealed in patches of filter-feeding bivalves, tube-building worms and seagrass.     

Benthic taxa as potential indicators of a deep-sea oil spill

The effect of the Deepwater Horizon oil spill on benthic macrofauna in the deep-sea Gulf of Mexico was measured in September–October 2010. Macrofauna community diversity and abundance were lowest closest to the wellhead and increased with distance from the wellhead up to 10 km. The macrofauna loss was primarily in surface sediments, which could be due to the deposition of oil and other toxic chemicals. Crustacean taxa appeared to be sensitive to the deep-sea blowout. Polychaete taxa varied in their sensitivity, but Dorvilleidae which is often associated with organic enrichment, was responsible for the largest amount of dissimilarity between stations close and far from the wellhead. Several other taxa were classified as sensitive or tolerant to the deep-sea blowout by comparing their distributions among impacted and non-impacted zones. The macrobenthic communities in the deep Gulf of Mexico exhibit a toxic response to the blowout on the Deepwater Horizon well, and this is correlated with barium and petroleum hydrocarbons.     

Recruitment response of methane-seep macrofauna to sulfide-rich sediments: An in situ experiment

Hydrodynamically unbiased colonization trays were deployed for 6 months (Oct. 2000 to April 2001) on the northern California margin (Eel R. region; 525 m) to examine macrofaunal colonization rates at methane seeps. The influence of sulfide on recruitment and survival was examined by deploying sediments with and without sulfide added; effect of seep proximity was evaluated by placing trays inside and outside seeps. The trays contained a two-layer system mimicking vesicomyid clam bed habitat geochemistry, with 8-9 mM sulfide in a lower agar layer at the start of the experiment. After 6 month on the seabed, the lower agar layer contained 2-4 mM H₂S. We observed rapid macrofaunal colonization equivalent to 50% of initial non-seep ambient densities. There was no difference in total colonizer densities, number of species, or rarefaction diversity among 3 treatments: (1) controls (no sulfide added) placed outside seeps, (2) trays with sulfide added placed outside seeps and (3) trays with sulfide added placed inside seep patches. Colonization trays with sulfide placed at seeps had different species composition from trays without sulfide place outside seeps; there were more amphipods (non-ampeliscid) and cumaceans in the seep/sulfide treatment and more nemerteans, Nephtys cornuta and tanaids in the non-seep/no-sulfide treatment. Outside seeps, annelids comprised < 15% of tray colonists; within seep patches, annelids comprised 5 of the top 10 dominant colonizing taxa (24% of the total). The polychaetes Mediomastus sp., Aphelochaeta sp., Paraonidae sp., and Nerillidae sp. exhibited significantly higher densities in sulfide additions. Tanaids, echinoderms, and N. cornuta exhibited sulfide avoidance. At least 6 dorvilleid polychaete species colonized the experiments. Of these, 4 species occurred exclusively in trays with sulfide added and 80% of all dorvilleid individuals were found in trays with sulfide placed inside seep sediments. Counts of large sulfur bacterial filaments were positively correlated with maximum sulfide concentration in each tray, and with proximity of sulfide to the sediment surface. However, total macrofaunal densities were not correlated with tray sulfide concentrations. As a group, tray assemblages achieved some but not all characteristics of ambient seep assemblages after 6-month exposure on the sea floor. Distinctive colonization patterns at methane seeps contribute to the dynamic mosaic of habitat patches that characterize the eastern Pacific continental margin.Overall, proximity of seep habitats had at least as great an influence on macrofaunal colonization as tray sulfide concentrations. Taxa characteristic of seep sediments were more likely to settle into trays placed inside rather than outside seep patches. Whether this is due to limited dispersal ability or local geochemical cues remains to be determined.     

Spatial pattern indicates an influence of barnacle and ascidian aggregations on the surrounding benthic assemblage

Joint clusters of solitary ascidians Styela spp., Bolthenia echinata (L.), Molgula spp. and barnacles Balanus crenatus Bruguiere in the White Sea subtidal often develop on shells or stones partially buried into muddy sediment. To assess the structuring role of these suspension-feeders' aggregations, we examined the spatial patterns of the surrounding infaunal assemblage. Pairs of cores obtained close to clusters (Close ones) and 20-25 cm away from them (Distant ones) were compared, the distance corresponding to the average distance observed between aggregations. These pairs were spatially grouped in replicas (blocks) tens of meters from each other. Out of 10 dominating invertebrate species found around the clusters (84 in total), 5 demonstrated significant difference in density (N) close to aggregations and between them. All the five, including polychaets Scoloplos armiger (Muller, Orbiniidae), Aricidea nolani (Eliason, Paraonidae), Heteromastus filiformis Zachs (Capitellidae), Chaetozone setosa Malmgren (Cirratulidae) and undetermined oligochaets, were associated with Close cores. Total abundance of polychaets, oligochaets, crustaceans and bivalves was also different in Close and Distant cores and indicated significant correlations (of either sign) with biomass estimates for barnacles and ascidians in each block. Individual mean body weight (IMW) in pairs of cores was different for 3 of 10 dominants, maldanid polychaets being larger close to clusters, and cirratulids being larger between them. For several taxa the difference, observed in both parameters (N and IMW), significantly varied between the replicas.Filter-feeding activity and faeces production are regarded as the main possible factors explaining the effect of barnacles and ascidians presence, since the spatial pattern observed corresponds with feeding types of the infaunal taxa studied. Average distance between the clusters was short enough, which allows us to conclude that the spatial distribution pattern of benthic infaunal species within the research area strongly depends on barnacle and ascidian aggregations mosaic.     

Hard rock versus soft bottom: the fauna associated with intertidal mussel beds on hard bottoms along the coast of Chile,and considerations on the functional role of mussel beds

The fauna associated with hard bottom mussel beds along the exposed Pacific coast of Chile was examined. The abundance of adult (>10 mm body length) purple mussels Perumytilus purpuratus varied between 32 and 75 individuals per 50 cm², and their biomass between 4.8 and 8.6 g AFDW per 50 cm² at eight sampling sites between Arica (18°S) and Chiloé (42°S). At all sampling sites, the associated fauna was dominated by suspension-feeding organisms (cirripeds, spionid and sabellid polychaetes, a small bivalve) followed by grazing peracarids and gastropods. Predators and scavengers also reached high abundances while deposit- and detritus-feeding organisms were of minor importance. The majority of organisms associated with these hard bottom mussel beds feed on resources obtained from the water column or growing on the mussels rather than on materials deposited by the mussels. This is in contrast to the fauna associated with mussel beds on soft bottoms, which comprises many species feeding on material accumulated by mussels (faeces and pseudofaeces) and deposited within the mussel bed. Many of the organisms dwelling between mussels both on hard bottoms and on soft bottoms have direct development, but organisms with pelagic development also occur abundantly within mussel beds. We propose that species with direct development are disproportionately favoured by the structurally complex habitat with diverse interstitial spaces between the mussels, which provides ample shelter for small organisms. We conclude that mussels on hard-bottoms primarily provide substratum for associated fauna while mussels on soft bottoms provide both substratum and food resources. Electronic Publication     

Impacts of boat-generated waves on macroinfauna: Towards a mechanistic understanding

Increasing evidence suggests that the waves produced by even low-wash vessels can have a sizeable impact on infaunal assemblages in otherwise sheltered estuaries. Although this impact is widely regarded to be a consequence of wash coarsening sediment grain-size, it may be due to a number of alternative mechanisms which include enhanced turbidity, decreased larval supply, changed resource availability and/or erosion of animals from the sediment. To increase understanding of impacts resulting from boat-wash, this study tested alternate mechanisms by which intertidal infauna along the Parramatta River, Sydney, Australia are impacted by wash from local ferries. Specifically, to discriminate between impacts of wash resulting from changes to sediment characteristics and impacts directly resulting from the altered hydrodynamic regime, cores of intertidal sediment were transplanted between a no-wash and a wash zone and within each of these zones. It was predicted that if wash indirectly determines the structure of assemblages by altering characteristics of the sediment: (1) sediment granulometry and/or mineralogy would differ between cores sourced from the wash zone and cores sourced from the no-wash zone; and (2) over a 6-week period during which sediment characteristics of transplanted cores do not appreciably change, assemblages transplanted across zones would remain more similar to assemblages at their origin than their destination. To the contrary, sediment grain-size did not differ among sites according to their location in wash or no-wash zones and the destination of sediment cores was more important than their origin in determining the structure of macroinvertebrate assemblages. Following transplant into the no-wash zone, the abundances of capitellids and nereids in cores of sediment from the wash zone rapidly increased in abundance. In cores of sediment transplanted from the no-wash zone to the wash zone, the abundances of these taxa decreased. The results of this study therefore indicate that impacts of boat-wash to infauna are not always a consequence of changes to sediment grain-size distribution. Thus, in order to successfully manage ecological impacts of boat-wash, other potential mechanisms such as erosion of sediments and changing resource availability also need to be considered.     

Whitemouth croaker Micropogonias furnieri (Desmarest, 1823) feeding strategies across four southern Brazilian estuaries

We test the hypothesis that predatory benthic fishes play a similar ecological role in different estuaries by displaying the same feeding strategy. We used whitemouth croaker (Micropogonias furnieri) populations in four southern Brazilian estuaries (Mampituba (29°12′ S), Tramandaí (30°02′ S), Patos Lagoon (32°10′ S) and Chuí (33°44′ S)) as a model. We compared feeding strategies based on a graphical method proposed by Amundsen et al. [(1996) J Fish Biol. 48:607–614], with confidence intervals of frequency of occurrence of prey (FO) and prey-specific abundance (PSA) estimated by bootstrap analyses. We test differences among diets in the four estuaries used the ANOSIM and SIMPER analyses. We minimize the effect of fish size on prey selectivity by restricting the diet analysis to 70–130 mm size classes. Across all estuaries, infaunal prey was the dominant item in the whitemouth croaker’s diet. Most individuals fed on dominant infaunal prey such as Polychaetes (Chuí: FO = 0.55 ± 0.018 SD; PSA = 0.88 ± 0.016 and Mampituba: FO = 0.73 ± 0.037; PSA = 0.56 ± 0.056), Bivalves (Tramandaí: FO = 0.58 ± 0.032; PSA = 0.92 ± 0.024) and Tanaidaceans (Patos Lagoon: FO = 0.63 ± 0.027; PSA = 0.62 ± 0.043). A between-phenotype contribution to the niche width was observed in all four estuaries, where individuals generally consumed relatively large amounts of different prey types in the same habitat and season. Whitemouth croaker have a zoobenthivore feeding strategy and seemed to maintain the same feeding strategy in all the four estuaries. Specialization on consuming infaunal prey displayed by juveniles of whitemouth croaker could be an important factor leading to the successful colonization of South American estuaries.     

Effects of chronic bottom trawling disturbance on benthic biomass, production and size spectra in different habitats

Bottom trawling has widespread impacts on benthic communities and habitats. It is argued that the impact of chronic bottom trawling on benthic infauna depends on the natural disturbance levels to which benthic communities are adapted. We analysed biomass, production and size structure of two communities from a muddy and a sandy habitat, in relation to quantified gradients of trawling disturbance on real fishing grounds. We used an allometric relationship between body mass and individual production to biomass ratio to estimate community production. Chronic trawling had a negative impact on the biomass and production of benthic communities in the muddy habitat, while no impact was identified on benthic communities from the sandy habitat. These differences are the result of differences in size structure within the two communities that occur in response to increasing trawling disturbance.