Maira Proietti

Marine Plastic Pollution in Waters around Australia: Characteristics, Concentrations, and Pathways

Plastics represent the vast majority of human-made debris present in the oceans. However, their characteristics, accumulation zones, and transport pathways remain poorly assessed. We characterised and estimated the concentration of marine plastics in waters around Australia using surface net tows, and inferred their potential pathways using particle-tracking models and real drifter trajectories. The 839 marine plastics recorded were predominantly small fragments (“microplastics”, median length = 2.8 mm, mean length = 4.9 mm) resulting from the breakdown of larger objects made of polyethylene and polypropylene (e.g. packaging and fishing items). Mean sea surface plastic concentration was 4256.4 pieces km−2, and after incorporating the effect of vertical wind mixing, this value increased to 8966.3 pieces km−2. These plastics appear to be associated with a wide range of ocean currents that connect the sampled sites to their international and domestic sources, including populated areas of Australias east coast. This study shows that plastic contamination levels in surface waters of Australia are similar to those in the Caribbean Sea and Gulf of Maine, but considerably lower than those found in the subtropical gyres and Mediterranean Sea. Microplastics such as the ones described here have the potential to affect organisms ranging from megafauna to small fish and zooplankton.

Millimeter-sized marine plastics: a new pelagic habitat for microorganisms and invertebrates.

Millimeter-sized plastics are abundant in most marine surface waters, and known to carry fouling organisms that potentially play key roles in the fate and ecological impacts of plastic pollution. In this study we used scanning electron microscopy to characterize biodiversity of organisms on the surface of 68 small floating plastics (length range = 1.7–24.3 mm, median = 3.2 mm) from Australia-wide coastal and oceanic, tropical to temperate sample collections. Diatoms were the most diverse group of plastic colonizers, represented by 14 genera. We also recorded ‘epiplastic’ coccolithophores (7 genera), bryozoans, barnacles (Lepas spp.), a dinoflagellate (Ceratium), an isopod (Asellota), a marine worm, marine insect eggs (Halobates sp.), as well as rounded, elongated, and spiral cells putatively identified as bacteria, cyanobacteria, and fungi. Furthermore, we observed a variety of plastic surface microtextures, including pits and grooves conforming to the shape of microorganisms, suggesting that biota may play an important role in plastic degradation. This study highlights how anthropogenic millimeter-sized polymers have created a new pelagic habitat for microorganisms and invertebrates. The ecological ramifications of this phenomenon for marine organism dispersal, ocean productivity, and biotransfer of plastic-associated pollutants, remains to be elucidated.

Artificial light on water attracts turtle hatchlings during their near shore transit

We examined the effect of artificial light on the near shore trajectories of turtle hatchlings dispersing from natal beaches. Green turtle (Chelonia mydas) hatchlings were tagged with miniature acoustic transmitters and their movements tracked within an underwater array of 36 acoustic receivers placed in the near shore zone. A total of 40 hatchlings were tracked, 20 of which were subjected to artificial light during their transit of the array. At the same time, we measured current speed and direction, which were highly variable within and between experimental nights and treatments. Artificial lighting affected hatchling behaviour, with 88% of individual trajectories oriented towards the light and spending, on average, 23% more time in the 2.25 ha tracking array (19.5 ± 5 min) than under ambient light conditions (15.8 ± 5 min). Current speed had little to no effect on the bearing (angular direction) of the hatchling tracks when artificial light was present, but under ambient conditions it influenced the bearing of the tracks when current direction was offshore and above speeds of approximately 32.5 cm s−1. This is the first experimental evidence that wild turtle hatchlings are attracted to artificial light after entering the ocean, a behaviour that is likely to subject them to greater risk of predation. The experimental protocol described in this study can be used to assess the effect of anthropogenic (light pollution, noise, etc.) and natural (wave action, current, wind, moonlight) influences on the in-water movements of sea turtle hatchlings during the early phase of dispersal.

Green turtles (Chelonia mydas) foraging at Arvoredo Island in Southern Brazil: genetic characterization and mixed stock analysis through mtDNA control region haplotypes

We analyzed mtDNA control region sequences of green turtles (Chelonia mydas) from Arvoredo Island, a foraging ground in southern Brazil, and identified eight haplotypes. Of these, CM-A8 (64%) and CM-A5 (22%) were dominant, the remainder presenting low frequencies (< 5%). Haplotype (h) and nucleotide (π) diversities were 0.5570 ± 0.0697 and 0.0021 ± 0.0016, respectively. Exact tests of differentiation and AMOVA ΦST pairwise values between the study area and eight other Atlantic foraging grounds revealed significant differences in most areas, except Ubatuba and Rocas/Noronha, in Brazil (p > 0.05). Mixed Stock Analysis, incorporating eleven Atlantic and one Mediterranean rookery as possible sources of individuals, indicated Ascension and Aves islands as the main contributing stocks to the Arvoredo aggregation (68.01% and 22.96%, respectively). These results demonstrate the extensive relationships between Arvoredo Island and other Atlantic foraging and breeding areas. Such an understanding provides a framework for establishing adequate management and conservation strategies for this endangered species.

Hawksbill × loggerhead sea turtle hybrids at Bahia, Brazil: where do their offspring go?

Hybridization between hawksbill (Eretmochelys imbricata) and loggerhead (Caretta caretta) breeding groups is unusually common in Bahia state, Brazil. Such hybridization is possible because hawksbill and loggerhead nesting activities overlap temporally and spatially along the coast of this state. Nevertheless, the destinations of their offspring are not yet known. This study is the first to identify immature hawksbill × loggerhead hybrids (n = 4) from this rookery by analyzing the mitochondrial DNA (mtDNA) of 157 immature turtles morphologically identified as hawksbills. We also compare for the first time modeled dispersal patterns of hawksbill, loggerhead, and hybrid offspring considering hatching season and oceanic phase duration of turtles. Particle movements varied according to season, with a higher proportion of particles dispersing southwards throughout loggerhead and hybrid hatching seasons, and northwards during hawksbill season. Hybrids from Bahia were not present in important hawksbill feeding grounds of Brazil, being detected only at areas more common for loggerheads. The genetic and oceanographic findings of this work indicate that these immature hybrids, which are morphologically similar to hawksbills, could be adopting behavioral traits typical of loggerheads, such as feeding in temperate waters of the western South Atlantic. Understanding the distribution, ecology, and migrations of these hybrids is essential for the development of adequate conservation and management plans.

Genetic Structure and Natal Origins of Immature Hawksbill Turtles ( Eretmochelys imbricata ) in Brazilian Waters

Understanding the connections between sea turtle populations is fundamental for their effective conservation. Brazil hosts important hawksbill feeding areas, but few studies have focused on how they connect with nesting populations in the Atlantic. Here, we (1) characterized mitochondrial DNA control region haplotypes of immature hawksbills feeding along the coast of Brazil (five areas ranging from equatorial to temperate latitudes, 157 skin samples), (2) analyzed genetic structure among Atlantic hawksbill feeding populations, and (3) inferred natal origins of hawksbills in Brazilian waters using genetic, oceanographic, and population size information. We report ten haplotypes for the sampled Brazilian sites, most of which were previously observed at other Atlantic feeding grounds and rookeries. Genetic profiles of Brazilian feeding areas were significantly different from those in other regions (Caribbean and Africa), and a significant structure was observed between Brazilian feeding grounds grouped into areas influenced by the South Equatorial/North Brazil Current and those influenced by the Brazil Current. Our genetic analysis estimates that the studied Brazilian feeding aggregations are mostly composed of animals originating from the domestic rookeries Bahia and Pipa, but some contributions from African and Caribbean rookeries were also observed. Oceanographic data corroborated the local origins, but showed higher connection with West Africa and none with the Caribbean. High correlation was observed between origins estimated through genetics/rookery size and oceanographic/rookery size data, demonstrating that ocean currents and population sizes influence haplotype distribution of Brazils hawksbill populations. The information presented here highlights the importance of national conservation strategies and international cooperation for the recovery of endangered hawksbill turtle populations.

Ingestion of plastics at sea: does debris size really matter?

Most of our knowledge on plastic ingestion by zooplankton comes from experiments exposing invertebrates to plastic particles smaller than their feeding apparatus. By examining millimetre-sized marine plastics using a scanning electron microscope, we putatively identified some surface textures as feeding marks produced by invertebrates grazing upon the plastic biofilm. We observed sub-parallel linear scrapes with 5-14 μm spacing, which is similar to typical distances between teeth of the mandibular gnathobases of copepods. We also observed peculiar rounded marks close to an unidentified marine worm. Small portions of the plastic particles were apparently removed, and perhaps ingested, during these putative grazing activities. Thus, we suggest that (1) plastic biofouling induces plastic ingestion, and (2) plastic pieces must not necessarily be smaller than the organism for a feeding interaction to occur. Experiments exposing invertebrates to millimeter-sized plastics may support these suggestions.

High Connectivity among Blue Crab (Callinectes sapidus) Populations in the Western South Atlantic

Population connectivity in the blue crab Callinectes sapidus was evaluated along 740 km of the Western South Atlantic coast. Blue crabs are the most exploited portunid in Brazil. Despite their economic importance, few studies report their ecology or population structure. Here we sampled four estuarine areas in southern Brazil during winter 2013 and summer 2014 in order to evaluate diversity, gene flow and structure of these populations. Nine microsatellite markers were evaluated for 213 adult crabs, with identification of seven polymorphic loci and 183 alleles. Pairwise FST values indicated low population structure ranging from -0.00023 to 0.01755. A Mantel test revealed that the geographic distance does not influence genetic (r = -0.48), and structure/migration rates confirmed this, showing that even the populations located at the opposite extremities of our covered region presented low FST and exchanged migrants. These findings show that there is a significant amount of gene flow between blue crab populations in South Brazil, likely influenced by local current dynamics that allow the transport of a high number of larvae between estuaries. Considering the elevated gene flow, the populations can be considered a single genetic stock. However, further information on population size and dynamics, as well as fishery demands and impacts at different regions, are necessary for harvest management purposes.

Extracting DNA from ocean microplastics: a method comparison study

The ubiquity of plastics in oceans worldwide raises concerns about their ecological implications. Suspended microplastics (<5 mm) can be ingested by a wide range of marine organisms and may accumulate up the food web along with associated chemicals. Additionally, plastics provide a stable substrate to a wide range of organisms and, owing to their widespread dispersal, may function as vectors for harmful and invasive species. Despite the growing application of molecular techniques to study ocean microplastic colonizers, to date there is no comparative study on DNA extraction methods for ocean plastic biofilms. The present study aims to fill this gap by comparing DNA yield, amplification efficiency, costs and processing time of different DNA extraction techniques applied to oceanic microplastics. DNA was extracted with five methods (four extraction kits, and standard phenol:chloroform purification) using two mechanical lysis techniques (bead beating and cryogenic grinding with liquid nitrogen) applied to three plastic quantities (1, 15, and 50 fragments per extraction) and size classes (0.05–0.15 and 0.15–0.5 mm). All methods resulted in DNA suitable for downstream applications and were successfully amplified. Overall, the Qiagen Puregene Tissue kit yielded relatively high DNA concentrations for most sizes and amounts of plastics at relatively low costs and short processing time. This study provides a detailed evaluation of DNA extraction methods from ocean plastics, and may assist future research using molecular techniques to study ocean plastic biofilms.

First record of the silver porgy ( Diplodus argenteus ) cleaning green turtles ( Chelonia mydas ) in the south-west Atlantic

The silver porgy (Diplodus argenteus) of the Sparidae is an occasional cleaner of two species of fish in the south-west Atlantic (Sazima, 1986; Krajewski, 2007). In a recent overview of fish that clean sea turtles (Sazima et al., 2010), 18 reef fish species in seven families are recorded as cleaners/grazers of epibionts of three turtle species of the Cheloniidae. Nine of these fish species (50%) are recorded for the south-west Atlantic (Sazima et al., 2010). The only sparid recorded associated with sea turtles is the sheepshead bream (Diplodus puntazzo), cleaning the loggerhead turtle (Caretta caretta) in the Mediterranean Sea off Greece (Schofield et al., 2006). We record herein for the first time a sparid (Diplodus argenteus) associating with green turtles (Chelonia mydas) and cleaning their carapaces in the south-west Atlantic. Field work was conducted at the rocky shores of Arvoredo Island (about 27817′S 48818′W), off Santa Catarina, southern Brazil. From 2004 to 2008, 334 SCUBA and snorkelling dives (227 hours) at depths 0.5–17 m were conducted in bays of Arvoredo Island, totaling 23 hours of direct underwater observation of turtle behaviour. Ad libitum and ‘behaviour’ samplings (Martin & Bateson, 1986) of general behaviours of focal animals were recorded in sessions that lasted 1–30 minutes. When a cleaning behaviour was sighted, both the turtle and the fish had their sizes estimated (curved carapace length (CCL) and total length (TL), respectively). One cleaned turtle was caught after a cleaning session to collect a sample of epibionts from the spot where the fish were feeding. Only immature individuals of the green turtle were recorded at the shores of Arvoredo Island, which seem to present a degree of residency at this protected area (Reisser et al., 2008). Silver porgy (Diplodus argenteus) juveniles 3–4 cm TL were observed repeatedly biting at the carapaces of green turtles (Chelonia mydas) 30–60 cm CCL on five occasions. One to two juvenile fish individuals feeding on the same turtle were recorded (Figure 1). The cleaned turtle was either swimming slowly in the water column (N 1⁄4 2) or hovering while feeding on red algae (Pterocladiella capillacea) belts on rocky reefs (N 1⁄4 3). The epibionts scraped from the green turtle were mostly Cyanobacteria (blue green ‘algae’) of the Chroococalles, both colonial (63.1%) and unicellular (27.6%), and Oscillatoriales including Lyngbya sp. (4.6%). Chlorophyta (green algae) comprised 3.7%, and the remaining microorganisms found on the carapace were Bacillariophyta (diatoms, 0.7%), and Ciliophora, Vorticellidae (ciliates, 0.2%). Juvenile porgies are omnivores that feed on benthic invertebrates, seaweeds, and zooplankton (Sazima, 1986; Carvalho-Filho, 1999), and most likely benthic microorganisms and epibionts such as those listed above are part of the diet of the small juveniles we recorded cleaning green turtles. Our findings are consistent with a study of the diet of the silver porgy in the same general area we conducted our observations (Dubiaski-Silva & Masunari, 2004). Juvenile silver porgies are able to change their cleaning stations while servicing fish (Krajewski, 2007), which is consistent with our observations of sea turtle cleaning. Our records, although admittedly few (N 1⁄4 5) demonstrate that juvenile porgies are able to move along with slowly swimming turtles, and that they join green turtles at their feeding grounds. Reef fish cleaning sea turtles has been claimed to be a localized phenomenon, restricted to particular populations and/or individuals (Losey et al., 1994). However, data from literature and the present study indicate that reef fish that graze on, clean, or use sea turtles as feeding grounds otherwise, are more common than the available records would indicate (Sazima et al., 2010). Corresponding author: I. Sazima Email: isazima@gmail.com