Phoronid larvae, actinotrochs, are beautiful and complicated organisms which have attracted as much, if not more, attention than their adult forms. We collected actinotrochs from the waters of the Pacific and Caribbean coasts of Panama, and used DNA barcoding of mtCOI, as well as 16S and 18S sequences, to estimate the diversity of phoronids in the region. We discovered three operational taxonomic units (OTUs) in the Bay of Panama on the Pacific coast and four OTUs in Bocas del Toro on the Caribbean coast. Not only did all OTUs differ from each other by >10% pairwise distance in COI, but they also differed from all phoronid sequences in GenBank, including the four species for which adults have been reported for the Pacific of Panama, Phoronopsis harmeri, Phoronis psammophila, Phoronis muelleri, and Phoronis hippocrepia. In each ocean region, one common OTU was more abundant and occurred more frequently than other OTUs in our samples. The other five OTUs were relatively rare, with only one to three individuals collected during the entire project. Species accumulation curves were relatively flat but suggest that at least one more species is likely to be present at each site. Actinotrochs from the seven sequenced OTUs had morphologies typical of species with non-brooded planktotrophic development and, in some cases, may be distinguished by differences in pigmentation and the arrangement of blood masses. We found one larva with morphology typical of brooded planktotrophic larvae for which sequencing failed, bringing the total number of potential species detected to eight and representing >50% of the adult species currently recognized globally.

The spatiotemporal variation of the distribution of echinoderms in the Georges Bank ecosystem was examined from 2005 to 2012. Density and abundance of representatives from echinoderm classes (brittle stars, sand dollars, sea stars, and sea urchins) were estimated using a drop camera video survey of the benthos in areas open and closed to fish trawling. The influence of closed areas on these echinoderm populations relative to a suite of key environmental and biotic factors was evaluated using Canonical Correspondence Analysis (CCA). While marine protected areas appeared to influence the distribution of sand dollars and sea stars, the distribution of brittle stars and sea urchins seemed to be defined mainly by preferred habitat conditions. According to the CCA, depth, sediment stability, temperature, predator abundance, and management area were the most important factors explaining this echinoderm assemblage. On Georges Bank, echinoderms dominate the benthic biota and are present in a variety of habitats. They can alter marine communities and are preferred prey and main predators for several commercially targeted species. The detailed information presented here (on the scale of kilometers) on abundance and spatial distribution of these populations is thus valuable towards the implementation of ecosystem-based fisheries management.

In the family Asterinidae, development through a planktonic lecithotrophic brachiolaria larva is common and has evolved independently several times. Here, we describe the lecithotrophic development of the asterinid Stegnaster inflatus, a species endemic to New Zealand. Early development through the blastula and gastrula stages is short, with hatching at the brachiolaria stage occurring within 48 hr. After hatching, larvae are negatively buoyant, and without aeration remain near the bottom of the culture containers. The settled benthic juvenile stage was reached in ∼2 weeks. The brachiolaria of S. inflatus shares common characteristics with the planktonic brachiolaria of other asterinids in that the brachiolar attachment apparatus comprises three brachia and a central adhesive disc, although the latter is thin and appears to be reduced. Mortensen (1925, Videns kabelige Meddelelser fra Dansk naturhistorisk Forening i København, 79(15), 261-420) had hypothesized that individuals of S. inflatus might brood within the “cave” formed in the interambulacral space between the arms. We found no evidence for brooding, but hypothesize that S. inflatus may have demersal development, on or near the bottom, which has implications for larval dispersal and population structure.

The European green crab(Carcinusmaenas)is a newly invasive species in Newfoundland, where it has likely been present for ≤15 years. The green crab has been found in stomach contents of American lobster (Homarus americanus) in New England and Nova Scotia, Canada, but predation on this species has not yet been quantified in Newfoundland. We conducted feeding experiments to determine whether lobsters from Newfoundland were as likely as those from Nova Scotia (which have coexisted with green crabs for >60 years) to recognize and prey upon this new species. We also performed experiments to determine whether green crabs reach a size refuge from predation and whether factors including starvation, availability of alternate food sources, or habitat complexity would influence the probability of lobster attacking or feeding on green crabs. In our trials, lobster origin had no significant effect on crab predation; lobsters, irrespective of origin, were more likely to consume small (<40 mm carapace width [CW]) and medium (40–65 mm CW) crabs than larger (>65 mm CW) ones. Nevertheless, even small lobsters (73–76 mm carapace length, 300 g) were able to kill and consume the largest green crabs (78 mm CW, 100 g). Green crabs were less likely to be attacked or eaten when an alternative food source was present, suggesting that the lobsters were preying on the crabs, rather than simply killing them in a dispute over territory. The addition of a shelter provided a refuge for the green crabs; however, the crabs were only able to avoid being injured or eaten if this shelter was structurally complex. The green crab is slowly spreading westward around the island of Newfoundland, and so its long-term effects, interactions with other organisms, and contribution to the diet of Newfoundland lobsters remain to be seen.

Ocean acidification is projected to inhibit the biogenic production of calcium carbonate skeletons in marine organisms. Antarctic waters represent a natural environment in which to examine the long-term effects of carbonate undersaturation on calcification in marine predators. King crabs (Decapoda: Anomura: Lithodidae), which currently inhabit the undersaturated environment of the continental slope off Antarctica, are potential invasives on the Antarctic shelf as oceanic temperatures rise. Here, we describe the chemical, physical, and mechanical properties of the exoskeleton of the deep-water Antarctic lithodid Paralomis birsteini and compare our measurements with two decapod species from shallow water at lower latitudes, Callinectes sapidus (Brachyura: Portunidae) and Cancer borealis (Brachyura: Cancridae). In Paralomis birsteini, crabs deposit proportionally more calcium carbonate in their predatory chelae than their protective carapaces, compared with the other two crab species. When exoskeleton thickness and microhardness were compared between the chelae and carapace, the magnitude of the difference between these body regions was significantly greater in P. birsteini than in the other species tested. Hence, there appeared to be a greater disparity in P. birsteini in overall investment in calcium carbonate structures among regions of the exoskeleton. The imperatives of prey consumption and predator avoidance may be influencing the deposition of calcium to different parts of the exoskeleton in lithodids living in an environment undersaturated with respect to calcium carbonate.

Aplysina red band syndrome (ARBS) affects shallow–water branching Caribbean sponges of the genus Aplysina. Signs of ARBS consist of a red band that advances from an initial circular lesion in both directions along the branch of the sponge, leaving behind spongin fibers devoid of living tissue. The red band is dominated by the filamentous cyanobacterium Leptolyngbya sp., which is responsible for the red coloration, although its role in the etiology of ARBS remains elusive. We used a combination of histology and transmission electron microscopy to describe ultrastructural and cellular differences between healthy and diseased individuals of Aplysina cauliformis. Tissue from the red band adjacent to spongin fibers devoid of living tissue was compared to healthy-appearing tissue on the same sponges and to healthy sponges. ARBS-affected tissue exhibited changes in cell densities, with increases in archaeocytes, collencytes, and unidentified round eukaryotic cells; decreases in exopinacocytes, granular cells, and spherulous cells; and loss of intact choanocyte chambers. Archaeocytes associated with diseased tissue appeared to be more active, as indicated by increased numbers and lengths of pseudopodia, and by a higher density of engulfed bacteria and symbiotic cyanobacteria, some of which were in various stages of disintegration. Filaments of Leptolyngbya sp. tended to be associated only with the ectosome of the red band portion of the lesion itself, and were rarely observed infiltrating intact tissue. These descriptions of anatomical and cellular responses to ARBS in A. cauliformis add to our understanding of the pathological effects of this widespread disease.

During deep-water exploratory surveys in the Mexican Pacific, 134 specimens of Galacantha diomedeae were collected between 1,035 and 2,136 m depth, below the Oxygen Minimum Zone. Greatest densities of G. diomedeae were observed between 1,300 and 1,600 m, with a maximum of 71 organisms per hectare at 1,318 m, and no clear bathymetric pattern of size distribution was detected. A total of 67 males, 43 ovigerous females, and 24 non-ovigerous females were collected. The global sex ratio was 1:1, with some predominance of females shallower than 1,300 m and the opposite pattern at 1,300–1,600 m. Ovigerous females (carapace width [CW]=15.5–32.3 mm) were significantly larger than other females (CW = 5.1–29.9 mm), and females (including all females) were larger than males (CW = 6.0–29.9 mm). Among males and among all females, the growth coefficient was near 3 (Student's t test, males = 0.0027, all females = 0.0041; for both males and females, p > 0.05), indicating isometric growth. Ovigerous females were present all year, except in January, suggesting continuous reproduction. The observed low numbers of eggs (11–126), large egg sizes (2.07–2.77 mm), and advanced embryos at stage 5 are consistent with extended, lecithotrophic embryonic development with a reduced pelagic phase of the larvae. The relationship between ovigerous female size (N = 43) and number of eggs per female was marginally significant (y = 8.0474x–98.297; R² = 0.373), and there was no significant relationship between egg size and carapace size. There was no clear increase in egg size with embryonic development (phases 1–5). Individuals of G. diomedeae were found in a narrow range of environmental conditions, and mainly occupied oxic water (DO ≥0.5 ml/L) and sediments with intermediate to low organic carbon content.

The aim of this study was to investigate vertical migration behaviors in two species of hygrophilous micro-snails, Vertigo moulinsiana and Vertigo angustior, in relation to the time of the year (spring and summer) at two sites that differ in ground water level (periodically inundated site and non-inundated site). The study shows different patterns of vertical migrations in the studied species. Vertigo angustior demonstrated a strong affinity to the litter layer (a weak tendency for vertical movements), independent of the time of year and site studied. By contrast, V. moulinsiana showed a clear tendency for vertical migrations, which differed depending on the time of year and site. These differences may be related to the spatial segregation of microhabitats used by these two species at the sites studied and to differences in the ability to resist inundation. Vertigo angustior is associated with microhabitats which are not subjected to prolonged inundation and tolerates a brief submersion. The periodic character of vertical migrations may suggest the effect of endogenous factors related to reproduction in V. moulinsiana. Some plasticity of this behavior in relation to habitat conditions demonstrated by this species may be an adaptation to live in unpredictably flooded environments.