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  • The seaweeds are a diverse group of large marine macroalgae that are as important to our near­shore coastal marine world as land plants are to our terrestrial world. Seaweeds were the evolutionary precursors to land plants, and like land plants, they are critical primary producers, forming living links between the inorganic and the organic world, using photosynthesis to convert CO2 and nutrients into living biomass. These primary producers support other marine life through the production of oxygen, their contribution to marine food webs, and by providing structure and habitat for fish and invertebrates. Seaweeds are also an important resource for humans. Historically, coastal peoples have relied on seaweeds for food, minerals, medicine, insulation, fertilizer and fodder. Today seaweeds are a multi­billion dollar industry worldwide, providing food, fertilizers, nutritional supplementation, and valuable phycocolloid extracts including agar, carrageenan, and alginate.

    Although wild harvest supports a significant portion of seaweed industry, there is an ever­increasing amount of seaweed production from aquaculture, principally in Asia and South America (Chile). Seaweed aquaculture makes up a significant portion of organisms cultured worldwide (~19 million metric tons) with a value of ~US $5.65 billion (FAO, 2012). Aquaculture production is dominated by kelps (Saccharina japonica and Undaria pinnatifida), tropical red algal species (carrageenophytes species including Kappaphycus and Eucheuma), nori (including Porphyra and Pyropia species), and the red algal agarophyte species known as Gracilaria. China is the world’s top producer of cultured seaweeds, though other countries in Asia (Japan, Korea, and the Philippines) and in Europe (France, Ireland, Norway, Scotland, and Spain) also grow seaweed. In North America, the seaweed industry is comprised of small wild­harvest cottage operations located along the East and West Coasts of Canada and the United States. Recent development in culture technologies, however, have led the to development of a small sugar kelp industry in the Northeast. As populations expand, culture of seaweed will be important to supplement the wild resource. Seaweeds can be cultivated in the sea on suspended lines, rafts, or nets, or on land in tank­based culture systems. A sustainable, low­ impact process, seaweed culture can provide much needed employment and independence to rural coastal communities. The development of a seaweed aquaculture industry can also encourage development of other aquacultured species that are higher up in the food chain. Seaweeds are bioextractive organisms, taking up excess nutrients generated by other species, such as fish or shrimp. The integrated culture of fed aquaculture (fish and shrimp) with extractive aquaculture (seaweed and shellfish) is called ‘Integrated Multi-Trophic Aquaculture’, or IMTA. The IMTA concept is an ecologically­based model that couples an inorganic bioextractive organism (seaweed) with an organic bioextractive organism (shellfish) to balance the intensive culture of fed organisms (finfish and shrimp), in order to produce a more sustainable, cleaner, and diversified aquaculture system (Neori et al., 2007). The development of new, ecologically based, sustainable culture technologies will ensure future employment for coastal communities, healthier coastal ecosystems, and the protection of important wild populations.

     

    There are many seaweed species in the Northeast with great economic and environmental potential. The three large kelp species Alaria esculenta, Laminaria digitata, and Saccharina latissima are eaten as healthy sea vegetables, usually sold as the “Atlantic” version of the similar Asian kelps (known as kombu or Wakame. They are an excellent source of iodine and other trace minerals, as well as a source of alginate, a phycocolloid used in many different industries (Sahoo and Yarish, 2005). Native red seaweeds include Gracilaria tikvahiae, Chondrus crispus, and Porphyra/Pyropia (previously referred to as Porphyra) species. Gracilaria species are cultivated at a large scale in some countries for food, as a feed for abalone, and for agar, an important phycocolloid in the food, medical, and microbiological industries. Chondrus crispus is eaten as a sea vegetable and used as a source of carrageenans, which are important in the food and consumer products industries as thickeners and stabilizers. Porphyra and Pyropia species (nori) species are cultivated on nets in Asia and are pressed and dried into the valuable nori sheets that are an integral part of the Asian diet. This manual serves as an introduction and instruction booklet for the nursery production and culture of the economically valuable seaweeds of New England, including locally occurring species of Saccharina, Gracilaria, Porphyra and Chondrus. It is our hope that it will be just the beginning of a successful and beneficial seaweed culture industry in the Northeast, whether for food, bioremediation, phycocolloids, animal feeds, biofuels, or any other of the potential uses of these versatile, wonderful seaweeds.

    Author(s): Yarish, Charles Sarah Redmond, Lindsay Green, Jang Kim, Christopher Neefus
  • Background and Objective: Eucheumatoid cultivation is increasing and a variety of methods exist that can increase production. However, new cultivation approaches are rarely reported. The objective of study was to examine a new method of seaweed cultivation: The floating cage.

    Materials and Methods: The growth rate of Eucheuma denticulatum and Kappahycus alvarezii was assessed in floating cages from March-November, 2015 and compared with that in the traditional longline approach. Propagule wet weight was measured daily to document growth rates. Correlation coefficients between growth rate and environmental factors were calculated using simple linear models (Pearsonʼs) and statistically analyzed by SPSS Version 24.

    Results: Growth rates of both species in floating cages were faster than on longline and thallus morphology was better. For E. denticulatum, the daily specific growth rate (SGR) in floating cages varied from a low of 2.68% to a high of 3.32%, but the respective rates on longline were 1.67 and 2.91%. For K. alvarezii cultivated in floating cages, the highest and lowest rates were 3.1 and 2.1% but, when cultivated on longline, the respective rates were 2.9 and 1.71%.

    Conclusion: Therefore, it was concluded that cultivation of E. denticulatum and K. alvarezii using floating cages resulted in higher growth rates compared to cultivation on longline. The difference in results comes from reduced herbivore attack when the plants are in the protective cages.

    Author(s): Ma'ruf Kasim, Ahmad Mustafa, Idul Male, Muzuni Jalil, Wardha Jalil
  • The red seaweed Laurencia viridis is a rich source of secondary metabolites derived from squalene. New polyethers, such as iubol (2), 22-hydroxy-15(28)- dehydrovenustatriol (3), 1,2-dehydropseudodehydrothyrsiferol (4), and secodehydrothyrsiferol (5) have been isolated and characterized from this alga. The structures were determined through the interpretation of NMR spectroscopic data and the relative configuration was proposed on the basis of NOESY spectrum and biogenetic considerations. All new compounds exhibited significant cytotoxic activity against a panel of cancer cell lines.

    Author(s): Antonio Hernández Daranas, José Javier Fernández, Manuel Norte Martín, Faustino Mollinedo, Janny A. Villa-Pulgarin, Francisco Cen Pacheco
  • In Norway, Seaweed Energy Solutions has patented the first ever modern structure to enable mass seaweed cultivation on an industrial scale in the world¹s oceans. The structure, known as the Seaweed Carrier, makes a clean break with past seaweed cultivation methods that have all been based on ropes. The Seaweed Carrier is a sheet-like structure that basically copies a very large seaweed plant, moving freely back and forth through the sea from a single mooring on the ocean floor.

    Author(s): Biofuels Digest
  • Since 2011, Dr. Charles Yarish and colleagues have experimented with growing seaweed on long lines at the head of New York's Bronx River Estuary, along with ribbed mussels suspended from a raft. They have raised a summer crop of the native red seaweed, Gracilaria tikvahiae, that grew up to 16.5% a day in July and a winter crop of sugar kelp, Saccharina latissima, that grew up to 8 feet in six months. Yarish says he has been surprised by the profigious growth in an area with low salinity and an overload of "a suite of nutrients" from a nearby waste water treatment plant and non-point runoff from the land and river. 

    Author(s): Muriel L. Hendrix
  • The University of Waikato Macroalgae Research Facility in Tauranga, New Zealand, has officially opened its new Facility of Aquaculture Research of Macroalgae.

    The cultivation research facility is focused on the development of sustainable technologies to enable the production of marine and freshwater macroalgae for biomass applications. This will ultimately deliver on New Zealand’s national targets to diversify the local aquaculture industry.

    The university partnered with Fresh By Design (FBD) to supply and build the new facility using recirculating aquaculture system (RAS). The system is comprised of two identical, bespoke algae research systems for both fresh and saltwater use. These are all housed in locally sourced greenhouses using reverse cycle heat pumps for temperature control, according to information obtained from FBD.

    Author(s): Mari-Len DeGuzman
  • Recent molecular phylogenetic investigations of the red algal genus Mastocarpus from the northeast Pacific resolved numerous cryptic species. Although species were clearly defined through genetic analyses, the correct names to apply to the species remained unclear due to both morphological variability within species and morphological similarity between species. To determine the appropriate name for each entity, we analyzed DNA from type material of taxa previously ascribed to Mastocarpus. In combination with this analysis, an updated phylogeny based on a broad range of geographical and morphological collections is presented that includes data from nuclear (ribosomal internal transcribed spacers [ITS]), chloroplast (rbcL) and mitochondrial [cytochrome oxidase I (COI)] genomes. By analyzing partial ITS region sequences of type specimens, we are able to match currently accepted names (Mastocarpus papillatus, M. pacificus and M. jardinii) to modern collections. We resurrect the following specific epithets and propose the new combinations Mastocarpus cristatus, Mastocarpus latissimus and Mastocarpus agardhii, and we create new species for which we were unable to verify an existing name: Mastocarpus alaskensis, Mastocarpus intermedius, Mastocarpus vancouveriensis, Mastocarpus californianus and Mastocarpus rigidus. The species formerly included in M. papillatus are now identified as Mastocarpus alaskensis, M. papillatus, Mastocarpus intermedius, Mastocarpus cristatus, Mastocarpus vancouveriensis and Mastocarpus latissimus. The name M. jardinii applies to a species thus far collected only from Moss Beach in San Mateo County and the Monterey Peninsula, both in California. Specimens other than the type previously assigned to M. jardinii are now separated into three species: Mastocarpus rigidus, Mastocarpus californianus and Mastocarpus agardhii. Mastocarpus cristatus represents a species closely allied to Clade 3 (Mastocarpus intermedius), and M. pacificus represents Clade 7. Morphological and anatomical diagnoses, along with vertical distributions and geographic ranges, are provided for each species. 

    Author(s): SANDRA C. LINDSTROM, JEFFERY R. HUGHEY, PATRICK T. MARTONE
  • The red seaweed, Gracilaria tikvahiae McLachlan, was cultivated in open water farms in urbanized estuaries of Long Island Sound (26-30 psu of salinity) and New York City (20-25 psu), USA in 2011. Plants were harvested monthly from summer (August, 24°C) to fall (November, 13°C) and analyzed for total nitrogen, protein, and amino acid content. On a dry matter (DM) basis, nitrogen and protein significantly increased over the harvest period until October and then pla-teaued. Nitrogen increased from 22 ± 1 g kg-1DM in August to 39 ± 3 g kg-1DM in October (p < 0.001). Protein increased from 107 ± 13 g kg-1DM in August to 196 ± 5 g kg-1DM in November (p < 0.001). With two exceptions, amino acid concen-trations expressed on a crude protein (CP) basis were similar over the harvest period. Essential amino acids accounted for 48 ± 1%of all amino acids present with lysine and methionine averaging 56 ± 2 g kg-1CP and 18 ± 1 g kg-1CP, respectively. Histidine was underrepresented among essential amino acids and averaged 13 ± 1 g kg-1CP. Taurine ranged from 2.1 to 3.2 g kg-1DM. With its moderate levels of lysine, methionine and taurine, ocean farmed G. tikvahiaehas the potential of overcoming many nutrient deficiencies currently associated with terrestrial plant ingredients in alternative feeds for fish and shrimp.

    Author(s): Yarish, Charles Ronald B. Johnson, Jang K. Kim , Lisa C. Armbruster
  • This study aims to evaluate seaweed Ulva reticulata preference for available nitrogen forms of eutrophic coastal waters for its growth rate. Simple experiment was developed for laboratorium testing of U. reticulata preference for NH 3 , NO 2 , NO 3 for 20 days. Levels of those nitrogen species and their composition were provided naturally from filtered eutrophic coastal waters of western coast of south Sulawesi Indonesia, without any exchange. The composition of NH 3 :NO 2 :NO 3 in the eutrophic water of the experiment was 1.0 : 2.4 : 3.3. The results showed that the NO 2 was the most preferred form of nitrogen for the growth. The average amount of uptake of NO 2 , NH 3 , and NO 3 was respectively 4.58 ± 1.71 μg/l/day, 2.70 ± 0.17 μg/l/day, and 1.98 ± 1.19 μg/l/day. The average growth rate of U. reaticulata was 15.40 ± 3.12 % day-1 .

    Author(s): Inayah Yasir, Muhammad Lukman, Ambo Tuwo, Andi Sompa
  • Aspects of the nutrient-uptake physiology of Porphyra dioica (Brodie et Irvine) from Porto, Portugal were investigated under laboratory conditions. The capacity for uptake and accumulation of nitrogen (N) by P. dioica was determined for two different N sources, ammonium and nitrate (). The influence of the light–dark cycle and of the simultaneous presence of and , as well as the effects of phosphorus (P) enrichment, on the growth, nutrient uptake, and accumulation were also evaluated. Porphyra dioica was able to take up, accumulate, and grow equally well using both sources of nitrogen when presented separately. The photosynthetic pigment levels increased significantly with the increase of the availability of N, for both sources. The chlorophyll a content was higher in thalli that used as source of N, while this difference was not seen for phycobiliprotein content. When both N sources were available (NO3 : NH4 = 6 : 1), P. dioica preferentially removed , with a clear diurnal difference. During the light period, the algae removed 70% of the available, while only 35% was removed during the dark period. Phosphorus enrichment did not influence the growth rate or the amount of P removed from the medium, suggesting a limited capacity to store P. These results indicate that P. dioica is a good candidate for application in an integrated multi-trophic aquaculture (IMTA) system.

    Author(s): Yarish, Charles Rui Pereira, George P. Kraemer, Isabel Sousa Pinto

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