A novel technique for propagation of Porphyra yezoensis Ueda blades in suspension cultures via monospores

The present methods for propagation of Porphyra blades in suspension cultures are inadequate for commercial production. A novel method for propagation of P. yezoensis blades in suspension cultures was tested. Blades were asexually propagated via monospores in suspension by cutting blades of various sizes into differently sized tissue sections and inoculating these in fresh medium. After 2–3 weeks, the sections completely disintegrated, producing monospores followed by a dense suspension culture of blades. This technique shows great promise for producing multiple crops from one initial blade inoculum, increasing production, and simplifying the propagation of this non-fragmenting alga in land-based tank mariculture. This revised version was published online in June 2006 with corrections to the Cover Date.     

A simple method to mass produce monospores in the thallus of Porphyra yezoensis Ueda

A simple method is presented for obtaining a large number of monospores in the thallus of Porphyra yezoensis. The method implies two principles: induction of monosporangium formation by allantoin, and liberation of monospores from the cell wall by mild homogenization. The induction of monosporangium formation was accomplished by culturing wild thalli in nutrient-enriched seawater with 10 mM of allantoin for approximately 3 weeks. This high concentration (10 mM) of allantoin suppressed the growth of the thalli compared with lower concentrations (0–1 mM). Thalli cultured for 3 weeks were mildly homogenized with a glass homogenizer and the monospore solution was obtained by filtering with a nylon mesh. The monospores grew normally to thalli. This technique of monospore acquisition is a simple and useful method for the propagation and breeding of P. yezoensis thalli.     

Forecasting infections of the red rot disease on Porphyra yezoensis Ueda (Rhodophyta) cultivation farms

Pythium porphyrae is a fungal pathogen responsible for red rot disease of the seaweed Porphyra (Rhodophyta). Infection forecasts of Porphyra by P. porphyrae were estimated from the epidemiological observations of Porphyra thalli and numbers of zoospore of P. porphyrae in laboratory and cultivation areas. Four features of forecasting infections were determined by relating zoospore concentrations to the incidence of thallus infection; infection (in more than 1000 zoospores L⁻¹), microscopic infection [less than 2 mm in diameter of lesion (in from 2000 to 3000 zoospores L⁻¹)], macroscopic infection [more than 2 mm in diameter of lesion (in from 3000 to 4000 zoospores L⁻¹), and thallus disintegration (in more than 4000 zoospores L⁻¹). High zoospore concentrations led to more infection. The tendency that zoospore concentration of P. porphyrae increased with the rate of infection of Porphyra thalli was generally observed in forecasting infections in both the laboratory and in cultivation areas. Based on the Porphyra cultivation areas, the accuracy and consistency of forecasting infections suggest that this method could be employed to manage and control red rot disease.     

Experimental tank cultivation of Porphyra in Israel

Outdoor tank cultivation of several Porphyra (nori) species was carried out from late November 2002 through early May 2003 using 40 L (with a surface of 0.25 m²), 600 L (1 m²), and 24,000 L (30 m²) fiberglass or PVC tanks provided with continuous aeration and seawater flow. Sexual and asexual spores produced from cultured conchocelis and frozen thalli in the laboratory, respectively, were subsequently grown to produce young fronds (ca. 5-10 cm) in an average time of 8 weeks. Growth in outdoor tanks and ponds was possible for a period of up to 20 weeks (i.e. growth season), with yields above 100 g FW m⁻²d⁻¹occurring during 12-14 weeks from late December through late March, when seawater temperatures were below 20 ^∘ C. These yields correlated with the species and depended on the type of tanks in which the algae were cultivated, with the highest yields observed for Porphyra sp. and Porphyra yezoensis when fertilized twice a week with NH₄ Cl and NaH₂ PO₄in 40 L tanks. Calculations of productivity for an entire growth season based on ≥ 100 g FW m⁻²d⁻¹yields exceed the average productivities using seeded nets in open sea, for all Porphyra species tested (0.96-4.06 kg DW m⁻² season⁻¹vs. 0.7-1.0 kg DW m⁻²of net season⁻¹). Therefore, tank cultivation of Porphyra can offer an additional source of nori biomass to international markets. Land-based tank cultivation also offers an environmentally friendly practice that allows for the manipulation of growth conditions to enrich seaweeds with specific, valuable chemicals such as protein and minerals.     

A preliminary comparison of the mariculture potential of Porphyra purpurea and Porphyra umbilicalis

Due to their rapid growth and nutrient assimilation,Porphyra spp. are good candidates for bioremediation and polyculture. The production potential of two strains of P. purpurea and P. umbilicalis from north-east USA was evaluated by measuring rates of photosynthesis (as O₂evolution) of material grown at 20 ^°C. Photosynthetic rates of P. umbilicalis were 80%higher than P. purpurea over the temperature range 5–20 ^°C, at both sub-saturating andsaturating irradiances (37 and 289 μmol photonm^-2 s^-1). Porphyra umbilicalis was more efficient at low irradiances (higher α) and had a higher P_max (23.0 vs 15.6 μmolO₂ g^-1 DW min^-1) than P.purpurea, suggesting that P. umbilicalis is a better choice for mass culture, where self-shading maybe severe. This revised version was published online in August 2006 with corrections to the Cover Date.     

Nori cultivation in North America: growth of the industry

The cultivation of the red alga Porphyra in North America to produce the edible product nori is now in its tenth year of development. Cultivation technology has been transferred and modified from Japan and Korea. Early efforts by the Washington State Department of Natural Resources indicated that cultivation is biologically feasible and could be economically viable. Commercial production has begun in Washington, U.S.A. and in British Columbia, Canada. Early products are of high quality. Constraints to more rapid development are institutional — obtaining necessary permits for use of water areas and financing is difficult.This paper is dedicated to the memory of Bud Brinkhuis — friend and fellow phycologist who will be missed by all of us growing seawwees.     

Procedures for the axenic isolation of conchocelis and monospores from the red seaweed Porphyra yezoensis

In order to maintain axenic seedstock cultures axenically of thecommercially important red seaweed, Porphyra yezoensis, aprocedure was developed for axenic isolation and culture of conchocelis andmonospores. For axenic isolation of the conchocelis, contaminated microalgaewere most effectively removed by filtering contaminated samples through a100-m mesh after sonication. Removal of bacteria and otheralgaewas accomplished using a mixture of 5 agents (0.02% chitosan, 100 gml^–1 GeO₂, 10 gml^–1 ampicillin, 40 gml^–1 kanamycin and 200 gml^–1 streptomycin). Axenic single colonies wereisolatedfrom a semi-solid medium prepared from 1% transfer gel. After collectingmonospores from the 40–50% density layer on a percoll-gradient, removalofbacteria and fungi from the monospores was accomplished using a mixture of 5antibiotics (3.5 g ml^–1 nystatin, 2 mgml^–1 ampicillin, 400 gml^–1 kanamycin, 50 gml^–1 neomycin and 800 gml^–1 streptomycin). Axenic single juvenile blades wereisolated from a semi-solid medium prepared from 0.5% transfer gel.     

Protoplast isolation and regeneration in the marine red alga Porphyra nereocystis

We have developed a method for isolating viable protoplasts from the blade phase of the epiphytic marine red alga Porphyra nereocystis Anderson, using a two-step enzymatic digestion with commercially available enzymes. The first step uses papain, the second step uses abalone acetone powder. The method is rapid and gives a high yield of viable protoplasts. In liquid culture in enriched seawater medium, the protoplasts can undergo regeneration along three pathways: they directly form filaments resembling the conchocelis phase of Porphyra; they form calli with relatively thick-walled, pigmented cells; and they indirectly form blades from the edges of these calli. Porphyra nereocystis protoplasts also may serve as an alternative propagation method in aquaculture and be useful for studies of cell-wall formation, cell division, and thallus differentiation. They may also be used in somatic selection, somatic hybridization and gene-transfection experiments.Abbreviations AAP abalone acetone powder - PAP papain - FDA fluorescein diacetate This paper is dedicated to the memory of the late Dr. Munenao Kurogi (1921–1988), Professor Emeritus of Hokkaido UniversityThis research was supported by the Washington Sea Grant Program (National Oceanic and Atmospheric Administration). We thank Professor Y. Fujita (Nagasaki University, Japan), Professor S.-J. Wang (Shanghai University of Fisheries, P.R. China) and Dr. H. Kito (Seikai Regional Fisheries Research Laboratory, Nagasaki, Japan) for sharing their experience with Porphyra protoplast production with us. We thank J.S. Charleston for expert technical assistance in preparation of the electron-microscopy specimens. We also thank Dr. S.K. Herbert and John Carrier (Friday Harbor Laboratories) and Dr. John Merrill and D. Gillingham (American Sea Vegetable Co. and Applied Algal Research, Seattle) for collections of P. nereocystis.     

An evaluation of species relationships in the Porphyra perforata complex (Bangiales,Rhodophyta) using starch gel electrophoresis

Traditional morphological features have formed the basis for distinguishing species of Porphyra. Among these features are number of cell layers, number of chloroplasts per cell, arrangement of reproductive structures on the thallus, and overall morphology. Chromosome number and chromosome morphology have helped corroborate some species identities. A survey of northeast Pacific species of Porphyra using starch gel electrophoresis of 15 soluble proteins has shown that electrophoretic banding patterns provide a reliable diagnostic tool for species identification. Data from starch gel electrophoresis are presented to confirm the identities of species formerly associated with the Porphyra perforata species-complex in British Columbia and northern Washington. Porphyra abbottae, P. fallax, P. kanakaensis, and P. torta are recognized as distinct species, and Porphyra sanjuanensis is synonymized with P. perforata.     

Life cycle of Porphyra vietnamensis Tanaka & Pham-Hoang Ho from Thailand

Porphyra vietnamensis Tanaka & Pham-Hoang Ho is a tropical species of high potential for farming. Studies of the life cycle have been conducted for many years but have not been successful until recently. Mature thalli were collected from Songkhla, in the southern part of Thailand, and were used to obtain Conchocelis in the laboratory in Bangkok. Conchocelis in shells as well as free-floating filaments could be observed after one week of incubation at 25 °C, 25 salinity and 350–500 lux light intensity, and covered the culture shell surface within 2 months. Conchosporangia were formed after being incubated for 10 days at 30 °C, 20 salinity under light intensities of 350–500 lux with a photoperiod of 12 hours a day. Induction of conchospore release was achieved by lowering the temperature to 25 °C and the salinity to 10–15 and increasing the light intensity to 800–1000 lux. Liberated conchospores germinated into young thalli which became mature after 70 days.     

Conchospore production and seasonal occurrence of some Porphyra species (Bangiales,Rhodophyta) in Washington State

The leafy thalli of species of the marine red algal genus Porphyra grow rapidly but persist for a relatively short time on rocky intertidal or subtidal substrata or as epiphytes on other marine plants. In most species, the large, short-lived leafy thalli alternate with small, presumably perennial, filamentous conchocelis plants. Depending on the species of northeastern Pacific Porphyra, photoperiod and temperature are important regulators of conchospore formation and release. Data from laboratory studies of conchospore formation and release in five Washington species of Porphyra (P. abottae, P. nereocystis, P. perforata, P. pseudolanceolata and P. torta) indicate that conchospores are most likely to be released at a time that precedes the appearance of the leafy thalli in the field.     

Rapid detection of Pythium porphyrae in commercial samples of dried Porphyra yezoensis sheets by polymerase chain reaction

The fungal parasite Pythium porphyrae is the causative organism of red rot disease in Porphyra cultivation farms. The detection of P. porphyrae from dried Porphyra yezoensis sheets was achieved using the species-specific primers PP-1 (5′-TGTGTTCTGTGCT-CCTCTCG-3′) and PP-2 (5′-CCCAAATTGGTGTTGCCTCC-3′) with the polymerase chain reaction (PCR). The DNA sequence (707 bp) of PCR product was found to be identical to that amplified from ITS rDNA extracted from a type species of P. porphyrae (IFO 30800, The Institute of Fermentation, Osaka, Japan). Quantities of the product amplified varied with the time when samples were harvested after the occurrence of red rot disease in Porphyra farms. This simple, rapid, and inexpensive method should have great applications in furthering quality control and determination of quality ranking in the Porphyra processing industry.     

Estimation of the degree of self-fertilization in Porphyra yezoensis (Bangiales,Rhodophyta)

Crosses between genotypically distinct thalli of the monoecious species Porphyra yezoensis were carried out using immature thallus fragments from green- and red-type color mutants and also wild-type thalli. As the genes governing the mutants are monogenic, recessive to the wild-type, and belong to the same linkage group, the degree of self-fertilization could be estimated based on the pigmentation of the resultant diploid conchocelis. The degree of self-fertilization in the cross between the green-type and the wild-type was 48.5–55.0%, and in the cross between the red-type and the wild-type was 45.1–56.5%. In the cross between the green- and red-type mutants, the degree of self-fertilization was 46.0–54.5% when the green-type was the female parent, and was 44.8–55.6% when the red-type was the female parent.