IDENTIFICATION AND CHARACTERIZATION OF THE CATALASE GENE PyCAT FROM THE RED ALGA PYROPIA YEZOENSIS (BANGIALES,RHODOPHYTA)1

Catalase is an antioxidant enzyme that plays a significant role in protection against oxidative stress by reducing hydrogen peroxide. The full‐length catalase cDNA sequence as isolated from expressed sequence tags (ESTs) of Pyropia yezoensis (Ueda) M. S. Hwang et H. G. Choi (PyCAT) through rapid amplification of cDNA ends (RACE) was identified and characterized. It encoded a polypeptide of 529 amino acids, which shared 36%–44% similarity with other known catalase proteins. Phylogenetic analysis revealed that PyCAT was closer to the catalases from plants than from other organisms. The PyCAT mRNA expression was investigated using real‐time PCR to determine life‐cycle‐specific expression and the expression pattern during desiccation. The mRNA expression level in gametophytes was significantly higher than in sporophytes, and the mRNA expression level of PyCAT was significantly up‐regulated during the desiccation process. The recombinant PyCAT protein was purified and analyzed biochemically. The recombinant PyCAT protein exhibited high enzymatic activity (28,000 U·mg^?1) with high thermal stability and a broad pH range. All these results indicate that the PyCAT is a typical member of the plant and algal catalase family and may play a significant role in minimizing the effect of oxidative damage in P. yezoensis during desiccation.     

VARIATIONS IN THE CELL WALLS AND PHOTOSYNTHETIC PROPERTIES OF PORPHYRA YEZOENSIS (BANGIALES,RHODOPHYTA) DURING ARCHEOSPORE FORMATION1

The formation of archeospores is characteristic of Porphyra yezoensis Ueda and is important for Porphyra aquaculture. Recently, it has been regarded as a valuable seed source for propagation of thalli in mariculture. Cell wall composition changes are associated with archeospore formation in P. yezoensis. Here, we report changes of cell walls of P. yezoensis during archeospore formation. The surfaces of vegetative cells that were originally smooth became rougher and more protuberant as archeosporangia were formed. Ultimately, the cell walls of archeosporangia ruptured, and archeospores were released from the torn cell walls that were left at distal margins of thalli. With changes in cell walls, both effective quantum yield and maximal quantum yield of the same regions in thalli gradually increased during the transformation of vegetative cells to archeospores, suggesting that the photosynthetic properties of the same regions in thalli gradually increased. Meanwhile, photosynthetic parameters for different sectors of thalli were determined, which included the proximal vegetative cells, archeosporangia, and newly released archeospores. The changes in photosynthetic properties of different sectors of thalli were in accordance with that of the same regions in thalli at different stages. In addition, the photosynthetic responses of archeosporangia to light showed higher saturating irradiance levels than those of vegetative cells. All these results suggest that archeosporangial cell walls were not degraded prior to release but were ruptured via bulging of the archeospore within the sporangium, and ultimately, archeospores were discharged. The accumulation of carbohydrates during archeospore formation in P. yezoensis might be required for the release of archeospores.     

ASSESSMENT OF PHOTOSYNTHETIC PERFORMANCE OF PORPHYRA YEZOENSIS (BANGIALES,RHODOPHYTA) IN CONCHOCELIS PHASE1

Photosynthetic characteristics of four Porphyra yezoensis Ueda [a taxonomic synonym of Pyropia yezoensis (Ueda) M. S. Hwang et H. G. Choi] strains in conchocelis phase were investigated and compared with one wildtype of P. yezoensis and two strains of Porphyra haitanensis T. J. Chang et B. F. Zheng [a taxonomic synonym of Pyropia haitanensis (T. J. Chang et B. F. Zheng) N. Kikuchi et M. Miyata]. Results showed that experimental strains had higher contents of chl a and carotenoids, but a lower content of total phycobiliproteins than the wildtype. Meanwhile, photochemical efficiency of PSII was measured using pulse amplitude modulation (PAM) fluorometry technology. The value of PSII photosynthetic parameters of P. yezoensis strains were all higher than the wild strain, and the maximal quantum yields (F_v/F_m), effective quantum yields Y(II), and relative photosynthetic electron transport rates (rETR) of P. haitanensis were higher than those of P. yezoensis. The present study verified the possibility of selective breeding of P. yezoensis using the filamentous sporophyte instead of the gametophytic thallus, the advantages being (i) nonrequirement of control of life cycle and (ii) direct and rapid cultivar improvement by artificial selection. We consider the method to be a promising technique for selective breeding of P. yezoensis cultivars.     

AXENIC TISSUE CULTURE AND MORPHOGENESIS IN PORPHYRA YEZOENSIS (BANGIALES, RHODOPHYTA)

To better understand developmental phenomena in macroalgal tissue culture, we examined the morphogenesis of Porphyra yezoensis Ueda (strain TU-1) cultured aseptically in defined synthetic media . Generally, the filamentous thalli (sporophyte; conchocelis phase) of P. yezoensis were densely tufted with uniseriate filaments. The foliose thalli (gametophyte) were monolayered. In this study, axenic filamentous thalli retained their characteristic morphogenesis; there were no obvious differences between morphogenetic traits in unialgal and axenic conditions. However, conchospores, which might have developed into the foliose form under unialgal conditions, germinated into calluslike masses under axenic conditions. Most of the gametophytes gradually lost their typical morphogenesis after the first longitudinal cell division. Some of the calluslike masses developed rhizoidlike structures in several places or along the entire mass. Therefore, we concluded that P. yezoensis, in axenic cultures, loses its typical morphogenesis only during the gametophytic phase. The axenic tissue culture of Porphyra established in this study is a promising assay system for the identification of growth and morphogenetic factors.     

TWO SPECIFIC CAUSES OF CELL MORTALITY IN FREEZE‐THAW CYCLE OF YOUNG THALLI OF PORPHYRA YEZOENSIS (BANGIALES,RHODOPHYTA)1

Porphyra yezoensis Ueda is an important marine aquaculture crop with single‐layered gametophytic thalli. In this work, the influences of thallus dehydration level, cold‐preservation (freezing) time, and thawing temperature on the photosynthetic recovery of young P. yezoensis thalli were investigated employing an imaging pulse‐amplitude‐modulation (PAM) fluorometer. The results showed that after 40 d of frozen storage when performing thallus thawing under 10°C, the water content of the thalli showed obvious effects on the photosynthetic recovery of the frozen thalli. The thalli with absolute water content (AWC) of 10%–40% manifested obvious superiority compared to the thalli with other AWCs, while the thalli thawed at 20°C showed very high survival rate (93.10%) and no obvious correlation between thallus AWCs and thallus viabilities. These results indicated that inappropriate thallus water content contributed to the cell damage during the freeze‐thaw cycle and that proper thawing temperature is very crucial. Therefore, AWC between 10% and 40% is the suitable thallus water content range for frozen storage, and the thawing process should be as short as possible. However, it is also shown that for short‐term cold storage the Porphyra thallus water content also showed no obvious effect on the photosynthetic recovery of the thalli, and the survival rate was extremely high (100%). These results indicated that freezing time is also a paramount contributor of the cell damage during the freeze‐thaw cycle. Therefore, the frozen nets should be used as soon as time permits.     

IDENTIFICATION OF CROSS‐FERTILIZED CONCHOCELIS USING CLEAVED AMPLIFIED POLYMORPHIC SEQUENCE MARKERS IN CROSS‐EXPERIMENTS OF PORPHYRA YEZOENSIS (BANGIALES,RHODOPHYTA)1

As a part of the construction of a Porphyra yezoensis Ueda genetic linkage map, we conducted intraspecific cross‐experiments and subsequent screening of cross‐fertilized conchocelis by cleaved amplified polymorphic sequence (CAPS) analysis. The cross‐experiments were carried out between males of the wildtype (KGJ) and females of the recessive green mutant (TU‐2) using two methods, controlled and random crosses. A total of 42 and 186 wildtype‐colored conchocelis colonies were obtained from the former and latter experiments, respectively. Among those, 49 DNA samples (14% and 23% obtained from the former and latter crosses, respectively) showed biparental CAPS patterns in the two gene regions (EF‐1α open reading frame [ORF] region and V‐ATPase). This study represents the first report in which the cross‐fertilized conchocelis of P. yezoensis has been directly confirmed by molecular marker. The combination of the simple DNA extraction and CAPS analysis may be applicable in genetic studies of other macroalgae that are monoecious and/or grow slowly in laboratory culture.     

MORPHOLOGICAL AND MOLECULAR ANALYSIS OF THE ENDANGERED SPECIES PORPHYRA TENERA (BANGIALES,RHODOPHYTA)1

Porphyra tenera Kjellman, widely cultivated in nori farms before the development of artificial seeding, is currently listed as an endangered species in Japan. To confirm whether a wild‐collected gametophytic blade was P. tenera or the closely related species P. yezoensis Ueda, morphological observations and molecular analyses were made on the pure line HGT‐1 isolated from a wild blade. This pure line was identified as P. tenera based on detailed morphological features. Sequences of the nuclear internal transcribed spacer region 1 and the plastid RUBISCO spacer revealed that P. tenera HGT‐1 was clearly different from P. yezoensis f. narawaensis Miura, the main species cultivated in Japan. PCR‐RFLP analysis of the internal transcribed spacer region was found to be a convenient method for rapid discrimination between P. tenera and cultivated P. yezoensis. The restriction patterns generated by the endonucleases Dra I and Hae III were useful for differentiating between both gametophytic and conchocelis stages of P. tenera HGT‐1 and P. yezoensis f. narawaensis strains. Thus, PCR‐RFLP analysis will serve as a valuable tool for rapid species identification of cultivated Porphyra strains, culture collections of Porphyra strains for breeding material and conservation of biodiversity, and, as codominant cleaved amplified polymorphic sequence markers for interspecific hybridization products between P. tenera and P. yezoensis f. narawaensis. Under the same culture conditions, rate of blade length increase and the blade length‐to‐width ratio were lower in P. tenera HGT‐1 than in P. yezoensis f. narawaensis HG‐4. The HGT‐1 became mature more rapidly than HG‐4 and had thinner blades.     

GENETIC DIVERSITY AND INTROGRESSION IN TWO CULTIVATED SPECIES (PORPHYRA YEZOENSIS AND PORPHYRA TENERA) AND CLOSELY RELATED WILD SPECIES OF PORPHYRA (BANGIALES,RHODOPHYTA)1

We investigated the genetic variations of the samples that were tentatively identified as two cultivated Porphyra species (Porphyra yezoensis Ueda and Porphyra tenera Kjellm.) from various natural populations in Japan using molecular analyses of plastid and nuclear DNA. From PCR‐RFLP analyses using nuclear internal transcribed spacer (ITS) rDNA and plastid RUBISCO spacer regions and phylogenetic analyses using plastid rbcL and nuclear ITS‐1 rDNA sequences, our samples from natural populations of P. yezoensis and P. tenera showed remarkably higher genetic variations than found in strains that are currently used for cultivation. In addition, it is inferred that our samples contain four wild Porphyra species, and that three of the four species, containing Porphyra kinositae, are closely related to cultivated Porphyra species. Furthermore, our PCR‐RFLP and molecular phylogenetic analyses using both the nuclear and plastid DNA demonstrated the occurrence of plastid introgression from P. yezoensis to P. tenera and suggested the possibility of plastid introgression from cultivated P. yezoensis to wild P. yezoensis. These results imply the importance of collecting and establishing more strains of cultivated Porphyra species and related wild species from natural populations as genetic resources for further improvement of cultivated Porphyra strains.     

ALLOPOLYPLOIDY IN NATURAL AND CULTIVATED POPULATIONS OF PORPHYRA (BANGIALES,RHODOPHYTA)1

To confirm whether allopolyploidy occurs in samples of previously identified Porphyra yezoensis Ueda, P. tenera Kjellm., and P. yezoensis × P. tenera from natural and cultivated populations, we examined these samples by using PCR‐RFLP and microsatellite analyses of multiple nuclear and chloroplast regions [nuclear regions: type II DNA topoisomerase gene (TOP2), actin‐related protein 4 gene (ARP4), internal transcribed spacer (ITS) rDNA and three microsatellite loci; chloroplast region: RUBISCO spacer]. Except for the ITS region, these multiple nuclear markers indicated that the wild strain MT‐1 and the cultivated strain 90‐02 (previously identified as P. yezoensis × P. tenera and cultivated P. tenera, respectively) are heterozygous and possess both genotypes of P. tenera and P. yezoensis in the conchocelis phase. Furthermore, gametophytic blades of two pure lines, HG‐TY1 and HG‐TY2 (F₁ strains of MT‐1 and 90‐02, respectively), were also heterozygous, and six chromosomes per single cell could be observed in each blade of the two pure lines. These results demonstrate that allopolyploidy occurs in Porphyra strains derived from both natural and cultivated populations, even though ITS genotypes of these strains showed homogenization toward one parental ITS.     

SIMILAR UNSTABLE MUTATIONS IN THREE SPECIES OF GRACILARIA (RHODOPHYTA)1

Unstable mutants with similar variegated pigmentation were genetically characterized in the red algae. Gracilaria tikvahiae (McLachlan), G. foliifera (Forsk.) Børg. and. G. sjoestedtii (Kylin). All three mutants were green plants with flecks of red tissue where cells had reverted to wild type. The mutant green phenotypes were all recessive, and their genetic behavior in crosses indicated that each was the result of a single, unstable, nuclear gene. Wild-type revertant tissue was stable one it arose. Revertant plants obtained from spores and revertant fronds taken from variegated plants could not be distinguished from the normal wild type, either phenotypically or genetically. Reversion to wild type occurred during all phases of the life cycle. In crosses between the mutants and wild type, most of the F₁ tetrasporophytes were heterozygous wild-type plants, an observation consistent with the recessive nature of the mutations; however, a low frequency of homozygous unstable-green F₁ tetrasporophytes was also obttained from these crosses. The molecular basis of neither the mutant instability, i.e. the reversion to wild type, nor of the process producing the unstable green F₁ tetrasporophytes can yet be deduced, but the phenotype of the plants and genetic results suggest the involvement of transposable genetic elements.     

IDENTIFICATION OF PORPHYRA HAITANENSIS (BANGIALES,RHODOPHYTA) MEIOSIS BY SIMPLE SEQUENCE REPEAT MARKERS1

The simple sequence repeat (SSR) marks were employed to identify the stage at which meiosis occurs in the life cycle of Porphyra haitanensis T. J. Chang et B. F. Zheng. More than 90% of F1 blades of heterozygous conchocelis produced by the cross between a red mutant (R, ♀) and the wildtype (W, ♂) were color sectored. Two parental colors (R and W) and two new colors (R′ and W′) appeared in linear sectors in the color‐sectored F1 blades. Two SSR primer pairs selected from a total of 52 primer pairs generated a specific paternal and maternal fragment, respectively. Co‐occurrence of these two bands was detected in heterozygous conchocelis and in the color‐sectored F1 blades with two to four sectors, such as R + W, R′ + W′, and R′ + R + W + W′. However, the single‐colored F1 blades exhibited only one band. In the sectors isolated from the color‐sectored F1 blades, R and R′ were the same, showing the maternal pattern, whereas W and W′ were the same, showing the paternal pattern. These data suggested that the two different bands from heterozygous conchocelis originated from the parents and segregated in the F1 blades, whereas the two new colors, R′ and W′, in the F1 blades were produced by the exchange and recombination of alleles of the parental colors during meiosis. These results indicated that meiosis of P. haitanensis occurs during the first two cell divisions of a germinating conchospore, and, therefore, the initial four cells constitute a linear genetic tetrad, leading to the formation of a color‐sectored blade.     

ULTRASTRUCTURE OF GERMINATING CARPOSPORES OF PORPHYRA VARIEGATA (KJELLM.) HUS (BANGIALES,RHODOPHYTA)1

The fine structure of released, attached, and germinating carpospores of Porphyra variegata (Kjellm.) Hus is described. Adhesive vesicles, formed during sporogenesis and discharged upon settling of the spore, produced a layer of adhesive mucilage around the spore and filled a deep imagination on the spore's ventral side. The mucilage layer was punctured by the emergence of a germ tube. Both spore and germ tube were lined by newly deposited cell wall. Germination was accompanied by vacuolation and starch mobilization. The morphological development of the sporeling was not noticeably influenced by the great variability of the timing, location, and orientation of septum formation. The attached carpospore possessed a plastid like that of gametophyte cells: stellate with one large central pyrenoid and no peripheral encircling thylakoids. Cells of mature vegetative cells of the conchocelis had plastids that were elongate and parietal and had multiple pyrenoids and encircling thylakoids. Most stages in the transition between the two forms of plastids occurred during carpospore germination.     

MEIOSIS,BLADE DEVELOPMENT,AND SEX DETERMINATION IN PORPHYRA PURPUREA (RHODOPHYTA)1

The discovery in the early 1980s that meiosis occurs during germination of conchospores of Porphyra yezoensis Ueda suggested that the sexually divided fronds of Porphyra purpurea (Roth) C. Agardh might similarly originate from meiotic segregation of a pair of sex-determining alleles during early sporeling development. After establishing conditions suitable for propagating P. purpurea in culture, observations on developing sporelings demonstrated that meiosis takes place during the first two divisions of the germinating conchospores. In the first division, the spore is split into an upper and lower cell. In the second, an anticlinal division in the upper cell yields two daughter cells situated one beside the other, and a periclinal division in the bottom cell gives two cells arranged one above the other. Thus, during normal development, the first four cells of the sporeling constitute a meiotic tetrad whose cells are arranged in a characteristic fashion. Stable color mutants of P. purpurea were isolated, genetically characterized, and used as genetic markers to follow the fate of individual cells of the tetrad during subsequent frond development. Nearly the entire blade of the mature thallus is derived from the two upper cells of the tetrad, with the two lower cells mostly giving rise to the rhizoidal holdfast region. Cell lineage boundaries laid down by the segregation of color alleles at meiosis corresponded perfectly with those later defined by sexual differentiation on the same fronds, strongly supporting the hypothesis that sex determination in P. purpurea is controlled by alleles at a segregating chromosomal locus.     

PHOTOSYNTHESIS AND RESPIRATION OF THE CONCHOCELIS STAGE OF ALASKAN PORPHYRA (BANGIALES,RHODOPHYTA) SPECIES IN RESPONSE TO ENVIRONMENTAL VARIABLES1

Photosynthesis and respiration of three Alaskan Porphyra species, P. abbottiae V. Krishnam., P. pseudolinearis Ueda species complex (identified as P. “pseudolinearis” below), and P. torta V. Krishnam., were investigated under a range of environmental parameters. Photosynthesis versus irradiance (P–I) curves revealed that maximal photosynthesis (P_max), irradiance at maximal photosynthesis (I_max), and compensation irradiance (I_c) varied with salinity, temperature, and species. The P_max of Porphyra abbottiae conchocelis varied between 83 and 240 μmol O₂ · g dwt^?1 · h^?1 (where dwt indicates dry weight) at 30–140 μmol photons · m^?2 · s^?1 (I_max) depending on temperature. Higher irradiances resulted in photoinhibition. Maximal photosynthesis of the conchocelis of P. abbottiae occurred at 11°C, 60 μmol photons · m^?2·s^?1, and 30 psu (practical salinity units). The conchocelis of P. “pseudolinearis” and P. torta had similar P_max values but higher I_max values than those of P. abbottiae. The P_max of P. “pseudolinearis” conchocelis was 200–240 μmol O₂ · g dwt^?1 · h^?1 and for P. torta was 90–240 μmol O₂ · g dwt^?1 · h^?1. Maximal photosynthesis for P. “pseudolinearis” occurred at 7°C and 250 μmol photons · m^?2 · s^?1 at 30 psu, but P_max did not change much with temperature. Maximal photosynthesis for P. torta occurred at 15°C, 200 μmol photons · m^?2 · s^?1, and 30 psu. Photosynthesis rates for all species declined at salinities <25 or >35 psu. Estimated compensation irradiances (I_c) were relatively low (3–5 μmol · photons · m^?2 · s^?1) for intertidal macrophytes. Porphyra conchocelis had lower respiration rates at 7°C than at 11°C or 15°C. All three species exhibited minimal respiration rates at salinities between 25 and 35 psu.     

PHYCOBILIN CONTENT OF THE CONCHOCELIS PHASE OF ALASKAN PORPHYRA (BANGIALES,RHODOPHYTA) SPECIES: RESPONSES TO ENVIRONMENTAL VARIABLES1

Variations of pigment content in the microscopic conchocelis stage of four Alaskan Porphyra species were investigated in response to environmental variables. Conchocelis filaments were cultured under varying conditions of irradiance and nutrient concentrations for up to 60 d at 11°C and 30 psu salinity. Results indicate that conchocelis filaments contain relatively high concentrations of phycobilins under optimal culture conditions. Phycobilin pigment production was significantly affected by irradiance, nutrient concentration, and culture duration. For Porphyra abbottiae V. Krishnam., Porphyra sp., and Porphyra torta V. Krishnam., maximal phycoerythrin (63.2–95.1 mg · g dwt^?1) and phycocyanin (28.8–64.8 mg · g dwt^?1) content generally occurred at 10 μmol photons · m^?2 · s^?1, f/4–f/2 nutrient concentration after 10–20 d of culture. Whereas for Porphyra hiberna S. C. Lindstrom et K. M. Cole, the highest phycoerythrin (73.3 mg · g dwt^?1) and phycocyanin (70.2 mg · g dwt^?1) content occurred at 10 μmol photons · m^?2 · s^?1, f nutrient concentration after 60 d in culture. Under similar conditions, the different species showed significant differences in pigment content. P. abbottiae had higher phycoerythrin content than the other three species, and P. hiberna had the highest phycocyanin content. P. torta had the lowest phycobilin content.     

CELL DIVISION PATTERNS AND DIURNAL CYCLE OF PORPHYRA ABBOTTAE (RHODOPHYTA,BANGIALES) CARPOGONIAL AND CARPOSPORE DEVELOPMENT1

Post-fertilization development of carpospores in Porphyra is a well-documented phenomenon. Development of the pre-fertilization carpogonial cells from vegetative cells, however, has not been previously described. In Porphyra abbottae Krishn., a rock? intertidal monostromatic species occurring from British Columbia to central California, large cells, designated hue CIS “procarpogonial mother cells” (PMCs), initiated the formation of the carpogonial cells. The PMCs formed during late night mitoses beginning at 0200 h with cytokinesis from 0300-0500 h during short day periods of 10:14 h LD in northern California (38°20′N, 123°03′W and 36°37′N, 121°55′W). The PMC cut off numerous smaller cells which in turn divided equal. Approximately 12 h Inter, at 1500 h (day 1) the Smaller cells were recognizable as carpogonial cells by the presence of trichogynes growing from the cytoplasm out through the cell wall to the thallus surface. In another 24 h (day 2), the fertilized carpogonia had divided into carpospore packets. Spores were released at 1500 h the following day (day 3), their projection creating escape channels through the cell walls.