Effect of water flow velocity on growth and morphology of cultured <Emphasis Type="Italic">Undaria pinnatifida</Emphasis> sporophytes (Laminariales,Phaeophyceae) in Okirai Bay on the Sanriku coast,Northeast Japan

Undaria pinnatifida sporophytes, originating from the same strain, were cultured at the commercial cultivation site exposed to wave action and the uncultivated site protected from water action of Okirai Bay, Northeast Japan, from January to April 2007; simultaneously, water flow velocity, water temperature, salinity, NO₃ + NO₂, and chlorophyll a were monitored to investigate the effect of water environment on their growth and morphology. Water temperature and salinity fluctuated within the optimal range for their growth whereas water flow velocity at the cultivation site was greatly fast compared with that at the uncultivated site. Successive chlorophyll a increases synchronized with NO₃ + NO₂ decreases were observed only at the uncultivated site for over a month; indicating developments of phytoplankton blooms and their nutrient consumption under the low-flow condition. Meanwhile, blade growth rate of cultured sporophytes was higher at the cultivation site than at the uncultivated site. Their thallus size expressed by six morphological characters (blade length, stipe length, blade wet weight, stipe wet weight, blade width, and undivided blade width) at the cultivation site became large in comparison with that at the uncultivated site. Their three morphological correlations (correlations between blade length and thallus length; blade wet weight and thallus wet weight; and undivided blade width and blade width) differed between the sites. They produced a thick and flat blade at the cultivation site but formed a thin and wrinkled blade at the uncultivated site. These results show the significant impact of water flow velocity on their growth and morphology.     

The occurrence of pinhole disease in relation to developmental stage in cultivated <Emphasis Type="Italic">Undaria pinnatifida</Emphasis> (Harvey) Suringar (Phaeophyta) in Korea

Infection rates of pinhole disease in farmed Undaria pinnatifida (Harvey) Suringar were examined between November 2002 and April 2003 at an Undaria farm at Wando on the southwestern coast of Korea. The growth stages of U. pinnatifida can be defined as: a growth phase from December to the end of February, and a decay phase from March to April. There was a significant increase in the level of infection with pinhole disease (measured as the number of pinholes per cm²) between December and April (P < 0.01). Infection progressed from the upper part of the frond in December to the basal part in April. The infection rate of pinhole disease in relation to growth phase on farms over time is limited by the harvest of the seaweed crop at the end of the cultivation period in April. The midrib, sporophyll and stipe showed no signs of infection at any time during the cultivation period. The reduced physiological activity and tissue aging that occurred over time in the sporophytic life phase is the probable cause of the increasing infection rate of the disease.     

Cultivation and utilization of Undaria pinnatifida (wakame) as food

A brief review is presented concerning wakame, Undaria pinnatifida, one of the most popular seaweeds used for food in Japan. Although it has been cultivated since about 1940, full-scale cultivation occurred after 1955. As methods for providing ‘seed stock’ and of processing the harvested sporophytes progressed, the yield increased rapidly. The main areas of cultivation are in Japan (e.g. Sanriku, Naruto), Korea and China, while ‘wild’ U. pinnatifida has been introduced into France, New Zealand and Australia. The total world yield of wakame exceeds 500 000 t fresh weight. Cultivated and harvested Undaria is boiled and salted (thus becoming green) and refrigerated; in the factory, it is removed its foreign matter and salt and dried. After checking for quality, the product is packaged in forms convenient for cooking and eating.     

Effects of experimental thinning on the growth and maturation of the brown alga Undaria pinnatifida (Laminariales; Phaeophyta) cultivated in Matsushima Bay,northern Japan

In northern Japan, massive production of high-quality specimens of the kelp Undaria pinnatifida prior to the traditional harvest season is strongly needed to meet commercial demand. To address this need, we tested the effects of controlled thinning by cutting small plants on the growth and maturation of sporophytes cultivated in Matsushima Bay, northern Japan. In early December 2009, the stocking densities of cultivated kelps were thinned to 10 and 5 plants per 4 cm thread section in two experimental groups. In contrast, no thinning was conducted during cultivation until March 2010 in the control group (about 16–20 plants per 4 cm thread section). Morphological features, photosynthesis, and carbon and nitrogen contents were compared among the three groups. Compared to kelps of control group, total length, stipe width, the length and width of sporophyll, and dry weights of blade and sporophyll showed significantly higher values in kelps of the two experimental groups. However, stipe length of kelps of control group was significantly greater than those of the two experimental groups. The photosynthetic rates and nitrogen contents of kelps of the two experimental groups were significantly greater than those of the control from January to March. No significant differences occurred in all these parameters between kelps of the two experimental groups. Based on these results, the growth and maturation of U. pinnatifida sporophytes can be promoted greatly by experimental thinning, and this will improve production of high-quality specimens of kelps and increase economic returns before the traditional harvest season.     

Effect of pre-incubation irradiance on survival of cryopreserved gametophytes of Undaria pinnatifida (Phaeophyta) and morphology of sporophytes formed from the gametophytes

Gametophyte strains originating from indigenous sporophytes of Undaria pinnatifida (Harvey) Suringar in Iwate Prefecture, Northeast Japan, were maintained for 9–10 months at 45 μmol photons m⁻² s⁻¹. Before cryopreservation in liquid nitrogen for more than 12 h (1–14 days) using a two-step cooling method with a mixture of cryoprotectants (10% l-proline and 10% glycerol), these were pre-incubated for 2, 4 and 8 months at 15 μmol photons m⁻² s⁻¹. After 1 week of thawing, no surviving gametophytes were detected in the strains without pre-incubation, but both the female and male gametophytes, pre-incubated for more than 4 months, showed high survival rates (43–60% for females and 64–100% for males). This revealed the induction of freezing tolerance by incubation at low irradiance. Thereafter, sporophytes derived from cryopreserved gametophytes and subcultured gametophytes, stored under pre-incubation conditions, were formed from the strain, and a morphological comparison was conducted with 10 characters (stipe length, stipe wet weight, blade length, blade wet weight, blade width, incision depth, blade thickness, sporophyll length, sporophyll wet weight, and sporophyll width). The morphology of the sporophytes formed from the cryopreserved gametophytes corresponded well with that of the subcultured gametophytes from the same strain. The results suggest that the cryopreservation method is applicable for preserving culture stocks of U. pinnatifida to be used in mariculture.     

Undaria pinnatifida (Laminariales,Phaeophyta) 12 years after its introduction into the Atlantic Ocean

Since its first introduction into the Atlantic for farming purposes in 1983, the brown alga Undaria pinnatifida has been found at several sites along the European coasts. The present study deals with an ecological experiment that was performed at the island of Ushant (Brittany, France) in order to check the ability of Undaria to recruit to a rocky substratum in situ. On the one hand, the authors were unsuccessful in getting Undaria to colonize a previously denuded area of shore, which was subsequently colonized by other native species, a result that may speak for a competition between Undaria and the local kelps. On the other hand, evidence is presented that Undaria pinnatifida has become a member of the Atlantic flora for good. The sporophytes can be found growing from low water mark of neap tide (+1.5 m) down to at least –15 m below lower water mark of spring tide. Its propagation is thought to occur in at least two ways: either step by step from cultivation sites along the coasts, or from the hulls of ships sailing from harbour to harbour. The preference of Undaria for settlement is on artificial structures.     

Effects of daylength,irradiance and settlement density on the growth and reproduction of <Emphasis Type="Italic">Undaria pinnatifida</Emphasis> gametophytes

The effects of daylength, irradiance and spore settlement density on the growth, maturation and sporophyte production of Undaria pinnatifida (Harvey) Suringar gametophytes were examined using a factorial experimental design in culture. The growth of Undaria gametophytes increased with increasing daylength (8, 12 and 16 h), but the maximum fertility occurred at a daylength of 12 h followed by 8 and 16 h. Gametophytes grew better at the 16 h daylength under the same mean daily irradiance (MDI) of 20 μmol photons m⁻² s⁻¹. However, the fertility was higher at the short daylength (8 h), indicating that the maturation of U. pinnatifida gametophytes is influenced by daylength rather than by the MDI. Vegetative growth and sporophyte production of gametophytes were better at 60 μmol photons m⁻² s⁻¹ than at 30 μmol photons m⁻² s⁻¹ under a 8:16 h LD (Light: Dark) cycle, and their growth and maturation were density-dependant in 16 and 12 h daylength, respectively. These results suggest that the U. pinnatifida gametophytes require a certain amount of light for the growth and reproduction, and intraspecific competition occurred under the optimal growth and maturation conditions. However, the sporophyte recruits per unit has been enhanced with increasing spore settlement density at 8 and 12 h daylengths indicating that high settlement density gives a benefit for maintaining population, even though the sporophyte production of each female plant is inhibited. In conclusion, the vegetative growth, reproduction and sporophyte production of U. pinnatifida gametophytes are retarded at a low irradiance above growth saturation and a high settlement density, and are determined by daylength.     

First Record of Undaria Pinnatifida (Laminariales, Phaeophyta) in Southern Patagonia, Argentina

The Japanese kelp Undaria pinnatifida was found on 7th September 2005 in Ría Deseado (Santa Cruz, Argentina). This invasive algae was registered from the lower intertidal to the upper levels of the subtidal zone. The sporophytes were fixed to slabs, gravel and rocks of variable sizes and were also present as epibionts of tunicates. The sporophytes total length ranged between 3 and 88 cm, with a mean of 28.75 cm in the intertidal and 38.3 cm in the subtidal. The density and biomass increased from the intertidal to the subtidal. The kelp population showed a higher number of small immature individuals in the intertidal than␣subtidal where the organisms were bigger and with more individual biomass. This first record of U. pinnatifida in Southern Patagonia extends its southern distribution limit in Argentina, showing progressive expansion in the southwestern Atlantic. More surveys must be conducted to understand the evolution of U. pinnatifida invasion and its impact on the native benthic community.     

Microscopic observations on tissue calcium distribution in the brown alga,Undaria pinnatifida (Harvey) Suringar

The distribution of Ca²⁺ in thallus tissues of the brown algaUndaria pinnatifida was investigated by microspectro-photometric analysis after fixation with Carnoy's reagent and staining with an alizarine sulfonate dye. Ca²⁺ accumulation in the young thallus was much higher in mucilage cells of the basal than the apical region; there was least in the pith of the basal region. A roughly uniform pattern was found in the stipe from the central part of the young thallus, while a highly irregular pattern occurred in both stipe and blade from the corresponding area of the mature thallus; the Ca²⁺ content was much lower than in the cortex, mucilage cells and vacuoles of the mature stipe than in the corresponding area of the young stipe. The contents of all regions of the mature blade were higher than those in the young blade; they were particularly high in mucilage cells.     

Growth and survival rates of large-type sporophytes of Ecklonia cava transplanted to a growth environment with small-type sporophytes

Stipe lengths of sporophytes of Ecklonia cava Kjellman have been reported to be longer along the southeast than southwest coast of the Izu Peninsula, central Japan. Two bays in this region that have natural populations of E. cava, but with different stipe lengths, were chosen for transplant experiments to examine if stipe length was an environmentally controlled trait. Transplant experiments were carried out in order to determine whether large-type sporophytes of E. cava with long stipes growing in Nabeta Bay (southeast Izu Peninsula, Japan) would turn into small-type sporophytes with short stipes when transplanted to Nakagi Bay (southwest Izu Peninsula). Ten juvenile sporophytes of E. cava (stipe length < 5 cm) were collected from Nabeta Bay (large-type habitat) and transplanted to Nakagi Bay (short-type habitat) in December 1995. As a transplant control, ten juvenile sporophytes of E. cava growing in Nakagi Bay were also transplanted to the same artificial reefs. Growth and survival rates of the sporophytes were monitored monthly for 3 y until December 1998. The transplanted sporophytes showed an increase in their stipe length and diameter from winter to spring, whereas almost no increase was observed from summer to autumn. However, the elongation was greater in Nabeta sporophytes than in Nakagi sporophytes. The primary blade length increased mainly from winter to early spring and decreased largely in autumn. Average primary blade lengths were similar in both Nabeta and Nakagi sporophytes from the end of the first year of transplanting. Although ca. 70% of both Nabeta and Nakagi sporophytes survived during the first 2 y after transplantation, no Nakagi sporophytes and only two Nabeta sporophytes survived to the end of the 3 y study period. Despite transplantation to Nakagi Bay, where short sitpes are naturally present, the sporophytes from Nabeta Bay persisted in having longer stipes, which suggests that stipe length is genetically, rather than environmentally, controlled.     

Regulation of Sorus Formation by Auxin in Laminariales Sporophyte

Young sporophytes of Laminaria japonica Areshoug were cultured in six indole-acetic acid (IAA) concentrations (0, 10⁻⁸, 10⁻⁷, 10⁻⁶, 10⁻⁵, 10⁻⁴ M) to examine the effect of auxin on growth. The effects of auxin on sorus formation were also examined by using discs taken from the adult sporophyte. The auxin contents and IAA oxidase activities in the thallus and sorus parts of the sporophyte were determined with the blade and sporophyll of other Laminariales plants, Undaria pinnatifida (Harvey) Suringar and Alaria crassifolia Kjellman. The young sporophytes of L. japonica showed highest elongation rate in 10⁻⁵ M IAA. In contrast, the sorus formation on the discs cultured in 10⁻⁵ M IAA was markedly delayed in comparison with other concentrations, indicating that sorus formation was suppressed by IAA. Free and conjugated auxin contents were lower in the reproductive parts than in the vegetative parts. In three Laminariales sporophytes, IAA oxidase activity was about 3–9 times higher in the reproductive parts than in the vegetative parts. Taken together these results suggest that the growth and reproduction of Laminariales sporophytes are regulated by internal auxin levels. Elucidating the regulation mechanism is likely to provide information that is important for the management of plant production and the assessment of the physiological status of plants in the field.     

Growth Promotion of Vegetative Gametophytes of <Emphasis Type="Italic">Undaria pinnatifida</Emphasis> by Blue Light

Through an acclimation period of 10 days, compared to white light, the maximal net photosynthetic rates were significantly higher for gametophytes of Undaria pinnatifida cultivated under blue light (400–500 nm), and were lower under red light (600–700 nm). Chlorophyll c and the carotenoid content of gametophytes were similar under blue light and red light but were much lower under white light. The growth rate of female gametophytes under blue light was higher than that under other lights, and the growth rate of male gametophytes showed little variation with respect to blue and white light. Male and female gametophytes were mixed together to form sporophytes under white, blue and red light. After approximately 5 days, 50% gametophytes became fertile under blue and white light, but remained vegetative under red light after 10 days.     

Undaria mitochondrial large subunit ribosomal DNA (Phaeophyceae, Alariaceae): Structural properties and use for phylogenetic analysis

We sequenced mitochondrial 23S ribosomal DNA (rDNA) from two Undaria species and compared them with homologous sequences from related brown algae. The 23S rDNA sequences from Undaria pinnatifida (Harvey) Suringar were 2707 bp in length, of which 1290–1292 sites were assigned to stem regions and the rest to loop regions in the rRNA secondary structure model. In Undaria undarioides (Yendo) Okamura, the sequences were 2708–2709 bp in length and 1290 sites were assigned to stems. There were three sequence types among the seven U. pinnatifida individuals examined and two among the four U. undarioides individuals. A maximum parsimony analysis of these sequence data with those from related brown algal species resolved a robust monphyly of each of the two Undaria species, suggesting the utilities of 23S rDNA for phylogeny at species or intraspecific level in brown algae. Accounting for variations among sequences parsimoniously, sequence changes were sorted into 423 events, of which 165 were mapped to stems of the secondary structure.     

Growth of Ecklonia cava (Laminariales, Phaeophyta) sporophytes transplanted to a locality with different temperature conditions

Transplanting experiments were carried out to determine whether the small type sporophytes with short stipe of Ecklonia cava Kjellman (Laminariales, Phaeophyta) growing in a locality with warm temperatures, change into larger type with a long stipe when transplanted to a locality with cooler temperatures. Juvenile E. cava sporophytes, having a stipe shorter than 5 cm long were collected from Tei in Tosa Bay (southern Japan) (seawater temperature 15–29°C) and transplanted to Nabeta Bay (central Japan) (seawater temperature 13–25°C), where larger type E. cava sporophytes characterized by long stipe (ca 1 m) grow. They were attached to artificial reefs at the sea bottom (9 m depth) in Nabeta Bay to monitor their growth. For comparison, juvenile E. cava sporophytes of almost similar size growing in Nabeta Bay were also transplanted in the same way to the same experimental site. Observations of growth of sporophytes from Tei and Nabeta were carried out monthly for 2 years from November 1995 to October 1997. The transplanted Tei and Nabeta sporophytes showed an increase in stipe length and diameter from winter to spring, whereas almost no increase was observed during summer and autumn. At the end of the study period, the stipe of Nabeta sporophytes reached 25.6 cm in length and 17.0 mm in diameter, whereas that of Tei sporophytes reached 11.1 cm in length and 11.2 mm in diameter. The primary blade length was 16.0 cm in Nabeta sporophytes, whereas it was 5.5 cm in Tei sporophytes. Thus, Tei sporophytes still remained smaller than Nabeta sporophytes even under the same environmental conditions.     

Compensation of the brown alga Undaria pinnatifida (Laminariales; Phaeophyta) after thallus excision under cultivation in Matsushima Bay, northern Japan

In recent years, the crop yield of cultivated Undaria pinnatifida (Harvey) Suringar has not been able to meet commercial demand and so advances in cultivation technology are strongly needed to increase production. Interestingly, cultivation work has shown the yield of U. pinnatifida sporophytes may be increased significantly by thallus excision, which may cause compensatory growth of the remaining tissues. To test this hypothesis and clarify correlative mechanisms, we examined seasonal morphological characteristics, photosynthetic rates, nutrient uptake rates, and carbon and nitrogen contents of U. pinnatifida sporophytes after thallus excision at a point 30 cm from the meristem in late February and compared these parameters with control kelps grown without excision, which were cultivated together in Matsushima Bay, northern Japan. Compared to control kelps, the length and dry weight of blades increased significantly after excision, and the growth phase was prolonged for about 1 month. The photosynthetic rates, nutrient uptake rates, and carbon and nitrogen contents of excised kelps were significantly higher than those of the controls. After vegetative growth stopped, resources accumulating in thalli were translocated significantly to sporophylls for maturation, indicating maturation was not negatively affected by thallus excision. These results indicate U. pinnatifida exhibits a very strong compensatory ability in response to thallus excision and consequently, the yield could be increased due to an increase in harvest frequency.     

Temperature requirements for the growth of young sporophytes of Undaria pinnatifida and Undaria undarioides (Laminariales, Phaeophyceae)

The relative growth rate of young sporophytes of Undaria pinnatifida (Harvey) Suringar and Undaria undarioides (Yendo) Okamura was examined in order to understand the difference in distribution of these two species around the coast of Japan. The optimal temperature for growth of both species was similar at 20°C and the upper critical temperature for growth was also similar, at 27°C for U. pinnatifida and 26°C for U. undarioides. Therefore, the optimal and upper critical temperatures for growth of the young sporophytes are not the main factors determining the distribution of each species. Next, the lower critical temperatures for growth were examined. For the young sporophytes of U. pinnatifida, the lower limit was less than 5°C while for those of U. undarioides it was 15°C. Thus, the difference in the lower critical temperature for growth between the two species was approximately 10°C. During the period of young sporophyte growth in the field, the temperature at the mouth of Ise Bay, Japan, where U. pinnatifida occurs, ranges from 12.7°C in December to 13.1°C in April, with a minimum of 7.9°C in February. Our experiments indicate that young sporophytes are able to grow throughout this period. The temperature off Hamajima, Japan, where U. undarioides occurs, ranges from 19.1°C to 14.8°C during the same time period. Again, young sporophytes are able to growth throughout this period, although minimum winter temperatures are only just high enough for growth. These natural temperature ranges during the growth season of the sporophytes agree well with the experimentally determined temperature requirements for growth of each species. Therefore, the difference between the two species in the critical temperature required for growth of the young sporophytes, especially in the low temperature range, is one of the major factors determining the distribution pattern of each species.     

Morphological variability of Undaria pinnatifida (Harvey) Suringar, 1873 (Phaeophyceae, Laminariales) in Peter the Great Bay, Sea of Japan

The morphological variability of the brown alga Undaria pinnatifida was studied in Peter the Great Bay (Sea of Japan). Comparison of the morphology of algae growing at eight sites of the bay that have different water movement revealed three phenotypically different population groups. A discriminant analysis of a set of morphological traits demonstrated that the width of the undivided part of the lamina and the stipe length make the most significant contribution to the discrimination of the detected groups. Analysis of the environmental dependence of morphological traits showed that lamina width and width of undivided part of lamina depend generally on water movement intensity, whereas the stipe length and thallus length are influenced by light intensity and surf degree.     

Epi-endophytic symbiosis between Laminariocolax aecidioides (Ectocarpales, Phaeophyceae) and Undaria pinnatifida (Laminariales, Phaeophyceae) growing on Argentinian coasts

The present is the first study on epi-endophytic algae on thalli of Undaria pinnatifida growing along Argentinian coasts. The main goal is to describe the nature and the morphology of this symbiosis. Individuals of Laminariocolax aecidioides were detected in both June and December 2004, growing on U. pinnatifida sporophytes. In nature, the epi-endophyte were macroscopically observed as dark zones that partially covered the hosts’ fronds. L. aecidioides vegetative thalli were irregularly branched uniseriate filaments. The life cycle is described from laboratory cultures started from Patagonian populations. Caryology revealed that the sporophytic diploid phase presented 16 chromosomes whereas the gametophytic haploid phase presented 8 chromosomes. Isolates made from thalli growing in the interior of infected hosts developed into filamentous, branched sporophytes that reproduced by both unispores and plurispores that were produced in unilocular and plurilocular sporangia, respectively. The results of this paper also allowed us to conclude that L. aecidioides uses the thalli of U. pinnatifida as a proper substrate. The penetration of endophitic filaments among the host′s cortical cells produced a lateral compression and, finally, their thalli development generated perforations in the host tissues. The effects of the epi-endophytic infection of L. aecidioides on U. pinnatifida are neither severe nor deleterious.     

Morphometric study of Ecklonia cava (Laminariales, Phaeophyta) sporophytes in two localities with different temperature conditions

Sporophytes of Ecklonia cava Kjellman (Laminariales, Phaeophyta) were collected seasonally from within 3–4 replicate, 1‐m² quadrates, haphazardly placed in dense assemblages at 6–9 m depth in Tei, Tosa Bay (southern Japan; water temperature 15–29°C) from 1995 to 1996, and in Nabeta Bay, Shimoda (central Japan; water temperature 13–25°C) from 1996 to 1997. Growth rings were checked for all samples and mean values of each biometric parameter of sporophytes 1‐year‐old and over were compared. The plant length (stipe length + primary blade length) was always shorter in Tei sporophytes (24–52 cm) than Nabeta sporophytes (70–100 cm), the difference being mainly owing to the shorter stipe length in Tei sporophytes (7–14 cm) than in Nabeta sporophytes (54–83 cm). However, the primary blade length was sometimes longer in Tei sporophytes (12–38 cm) than in Nabeta sporophytes (14–21 cm). Stipe diameter, longest bladelet length and primary blade width were mostly less in Tei sporophytes (8.6–12.4 mm, 5.5–7.0 cm and 23.4–38.0 cm, respectively) than Nabeta sporophytes (16.4–20.2 mm, 9.2–12.0 cm and 43.0–52.6 cm, respectively). Nevertheless, the number of bladelets of sporophytes from Tei (15–28) and Nabeta (18–29) were within the same range. At Tei, 32–43% of the sporophytes had wrinkled blades in summer and autumn, whereas wrinkled primary blades or bladelets were not observed in Nabeta sporophytes throughout the experimental period. These morphometric differences of E. cava between the two localities are suggested to be dependent on environmental factors, especially seawater temperature.     

The genetic analysis and germplasm identification of the gametophytes of Undaria pinnatifida (Phaeophyceae) with RAPD method

Eleven pairs of Undaria pinnatifida (Harv.) Suringar gametophytes were identified with random amplified polymorphic DNA (RAPD) technique. After screening 100 primers, 20 ten-base primers were determined for the RAPD analysis. A total of 312 polymorphic loci were obtained, of which 97.7% were polymorphic. The primer S198 was found to distinguish all the selected Undaria pinnatifida gametophytes. The genetic distances between each two of the twenty-two U. pinnatifida gametophytes ranged from 0.080 to 0.428, while the distances to the Laminaria was 0.497 on average. After reexamination, two sequences characterized amplification region (SCAR) markers were successfully converted, which could be applied to U. pinnatifida germplasm identification. All these results demonstrated the feasibility of applying RAPD markers to germplasm characterization and identification of U. pinnatifida gametophytes, and to provide a molecular basis for Undaria breeding.