Genetic analysis of the position of meiosis in <Emphasis Type="Italic">Porphyra haitanensis</Emphasis> Chang et Zheng (Bangiales,Rhodophyta)

Crossing experiments were carried out between artificial pigmentation mutants and the wild type in Porphyra haitanensis Chang et Zheng to ascertain where meiosis occurs in its life history by confirming whether the color segregation and the color-sectored blades appear in F₁ gametophytic blades developed from conchospores which are released from heterozygous conchocelis. Two red-type pigmentation mutants (R-10 and SPY-1) were used as the female parent. Their blades are red or red orange in color, thinner than the wild type and weak in elasticity, and have no denticles on their margins. The wild type (W) was used as the male parent; its blades are light brown in color, thick and good in elasticity, and have many marginal denticles. The F₁ gametophytic blades developed from conchospores which were released from heterozygous conchocelis produced in the crosses of R-10(♀)×W(♂) and SPY-1(♀)×W(♂) showed two parental colors (R and W) and two new colors (R', lighter in color than R; W', wild-type-like color and redder than W). Linear segregation of colors occurred in the F₁ blades, forming color-sectored blades with 2–4 sectors. In the color-sectored blades, R and R' sectors were thinner than W and W' sectors, and had weak elasticity and no denticles on their margins, whereas W and W' sectors were thick and had good elasticity and many marginal denticles. Of the F₁ gametophytic blades, 95.2–96.7% were color-sectored and only 3.3–4.8% were unsectored. These results indicate that meiosis of P. haitanensis occurs during the first two cell divisions of a germinating conchospore, and thus it is considered that the initial four cells of a developing conchosporeling constitute a linear genetic tetrad leading to the formation of a color-sectored blade. The new colors of R' and W' were recombinant colors due to the chromosome recombination during the first cell division in meiosis. It is considered that color phenotypes of the two mutants used in this paper were result of two (or more) recessive mutations in different genes, and that they also have mutations concerned with blade thickness and formation of marginal denticles, which are linked with the color mutations.     

Genetic analysis of artificial pigmentation mutants in Porphyra yezoensis Ueda (Bangiales, Rhodophyta)

Porphyra yezoensis Ueda artificial pigmentation mutants, yel (green), fre (red‐orange) and bop (pink), obtained by treatment with /V‐methyl‐/V′‐nitro‐N‐nitrosoguanidine, were genetically analysed. The mutations associated with color phenotypes are recessive because all of the heterozygous conchocelis resembled the wild type color when they were crossed with the wild type (wt). In the reciprocal crosses of yel × wt, both parental colors and eight types of blades appeared in the F₁ gametophytic blades from the heterozygous conchocelis. Both colors segregated in the sectored F₁ blades in a 1:1 ratio, indicating that the color pheno‐type of yel resulted from a single mutation in the nuclear gene. In the reciprocal crosses of fre × wt, however, four colors and more than 40 types of blades appeared in the F₁ blades from the heterozygous conchocelis, indicating that the color phenotype of fre resulted from two mutations in different genes. In the reciprocal crosses of bop×wt, three colors and 12 types of blades were observed in the F₁ blades from the heterozygous conchocelis. Both parental colors appeared far more frequently than the third new color. These results indicated that the color phenotype of bop resulted from two closely linked mutations in different genes, and the epistasis occurred in the F₁ blades. The mutants, yel, fre and bop, differ from the spontaneous green (C‐O), the red (H‐25) and the violet (V‐O) mutants of P. yezoensis, respectively.     

CHIMERAS WITH MOSAIC PATTERN IN ARCHEOSPORE GERMLINGS OF PYROPIA YEZOENSIS UEDA (BANGIALES,RHODOPHYTA)1

In the marine crop Pyropia yezoensis (Ueda) M. S. Hwang et H. G. Choi, it is known that conchospores from heterozygous conchocelis develop into sectored gametophytic blades (chimeras), but archeospores asexually released from haploid blades do not usually grow into chimeric blades. In this study, chimeras with mosaic pattern consisting of the green and wildtype colors were developed from archeospores that were released from a blade piece containing a cell cluster of green color induced by heavy‐ion beam irradiation. To make clear whether these archeospores were produced from the green‐colored cells or the wildtype‐colored cells, cell clusters of the green mutant, wildtype, and mosaic pattern were cut out from the grown chimera, and archeospores were released from each of the three blade pieces. Archeospores from the green‐mutant blade piece and from the wildtype blade piece developed into only green‐mutant blades and wildtype blades, respectively. In contrast, archeospores from the blade piece with mosaic pattern developed into green‐mutant blades, wildtype blades, and chimeric blades with mosaic pattern of the two colors, although the frequency of the chimeras was low. Because each gametophytic cell possesses a single plastid, it is difficult to explain the occurrence of the new chimeras as a mutation of the plastid DNA. Thus, the new chimeras are considered to be due to transposable elements in Pyropia.     

The characterization of color mutations in Bangiaceae (Bangiales, Rhodophyta)

The color mutations in Bangiaceae were investigated by treating the blades, conchocelis and conchospores phase of Bangia sp., Porphyra yezoensis, and P. haitanensis sampled in China with mutagen N-methyl-N′-nitro-N-nitrosoguanidine (MNNG). A high percentage of mutation in different expression characteristics in all three phases were shown within optimum mutagen concentrations. Among mutagenized blades, mutations occurred on single cells, which is a direct outcome of mutation of haploid cells. The mutation of mutagenized conchocelis resulted in a two-step process: low-level expression in conchocelis phase, and high-level expression in progeny, explaining that mutation took place in diploid cells. The mutations of conchospores were expressed immediately at germination of spores, indicating a change in ploidy. This paper reports the process of meiosis and its effect on frond development, and the relation between color mutations and morphological characteristics expressed by mutations in Bangiaceae.     

Purification of R‐phycoerythrin from Porphyra haitanensis (Bangiales,Rhodophyta) using expanded‐bed absorption1

R‐phycoerythrin (R‐PE) was purified from leafy gametophyte of Porphyra haitanensis T. J. Chang et B. F. Zheng (Bangiales, Rhodophyta) by a simple, scaleable procedure. Initially, phycobiliproteins were extracted by repeated freeze‐thaw cycles, resulting in release from the algal cells by osmotic shock. Next, R‐PE was recovered by applying the crude extract with a high concentration of (NH₄)₂SO₄ salt directly to the expanded‐bed columns loaded with phenyl‐sepharose. An expanded‐bed volume twice the settled‐bed volume was maintained; then low (NH₄)₂SO₄ concentration was used to develop the column. After two rounds of hydrophobic interaction chromatography (HIC), R‐PE was purified by anion‐exchange column. The method was also successful with free‐living conchocelis of P. haitanensis. The purified R‐PE was identified with electrophoresis, and absorption and fluorescence emission spectroscopy. The results were in agreement with those previously reported. The yield with a spectroscopic purity (OD₅₆₅/OD₂₈₀) higher than 3.2 (the ratio of A₅₆₅/A₆₂₀ ≤ 0.02) was 1.4 mg · g^?1 of leafy gametophyte of P. haitanensis. For the free‐living conchocelis of P. haitanensis extract, R‐PE could be purified successfully with only one round of HIC. The yield with a spectroscopic purity (OD₅₆₅/OD₂₈₀) higher than 3.2 (the ratio of A₅₆₅/A₆₂₀ ≤ 0.02) was 5.0 mg · g^?1 of free‐living conchocelis of P. haitanensis. The method described here is a scaleable technology that allows a large quantity of R‐PE to be recovered from the unclarified P. haitanensis crude extract. It is also a high protein recovery technology, reducing both processing costs and times, which enhances the value of this endemic Porphyra of China.     

New life cycles of <Emphasis Type="Italic">Porphyra katadae</Emphasis> var. <Emphasis Type="Italic">hemiphylla</Emphasis> in culture

Porphyra katadae Miura var. hemiphylla Tseng et T. J. Chang, a species distributed around the Liaodong and Shandong Peninsulas of China, produces gametophytes from late winter to early spring. These are monoecious with male and female reproductive tissues in distinct halves or sectors. Vegetative tissues from sectors expected to differentiate into sexual tissue were cultured in the laboratory. Male and female reproductive organs, as well as conchocelis and blades, were differentiated from these tissues. The male and female reproductive tissues were in patches and mixed on the cultured tissue pieces. This was quite different from the wild-type sectored individuals. The F₁ conchospore germlings also produced monospores, carposporangia, spermatangia and conchocelis. These carposporangia and spermatangia were in patches and were mixed on the F₁ fronds. The results imply that P. katadae var. hemiphylla is possibly sex-differentiated rather than sex-determined. This is the first report of such a dimorphic life history in the genus Porphyra.     

Free amino acid contents of the gametophytic blades from the green mutant conchocelis and the heterozygous conchocelis in Porphyra yezoensis Ueda (Bangiales, Rhodophyta)

Free amino acid contents in green mutant(G-1) blades and sectored F₁gametophytic blades with green andwild-type portions, which were developedfrom heterozygous conchocelis obtained by across between the wild type (0110) and thegreen mutant (G-1) of Porphyrayezoensis, were compared with those of thewild-type blades in laboratory culture. The contents of the major four free aminoacids (aspartic acid, glutamic acid,alanine and taurine) as well as those ofthe total free amino acids were highest inthe green mutant blades, intermediate inthe F₁ gametophytic blades, and lowestin the wild-type blades. A similar trendwas obtained in the blades developed frommonospores of the F₁ gametophyticblades. In addition, the green-typesectors also had a higher content of thefour major free amino acids and total freeamino acids compared with the wild-typesectors in the F₁ blades cultivated ata nori farm. The green mutant ischaracterized by higher contents of thefour major free amino acids compared withthe wild type, which has a higher growthrate. Hence, it is considered that thesectored F₁ gametophytic bladesproduced from the heterozygous conchocelishave both parental advantages (high freeamino acid contents and high growth rate)and compensate for both parentaldisadvantages. This seems to be one of thepossible ways of genetic improvement inregards to the taste of nori and stableproduction in Porphyra cultivation.     

INTERSPECIFIC HYBRIDIZATION IN THE HAPLOID BLADE‐FORMING MARINE CROP PORPHYRA (BANGIALES,RHODOPHYTA): OCCURRENCE OF ALLODIPLOIDY IN SURVIVING F1 GAMETOPHYTIC BLADES1

We performed interspecific hybridization in the haploid blade‐forming marine species (nori) of the genus Porphyra, which have a heteromorphic life cycle with a haploid gametophytic blade and a diploid microscopic sporophyte called the “conchocelis phase.” The green mutant HGT‐6 of P. tenera var. tamatsuensis A. Miura was crossed with the wildtype HG‐1 of P. yezoensis f. narawaensis A. Miura; the F₁ heterozygous conchocelis developed normally and released numerous conchospores. However, almost all the conchospore germlings did not survive past the four‐cell stage or thereabouts, and only a few germlings developed into gametophytic blades. These results indicate that hybrid breakdown occurred during the meiosis, while the surviving F₁ gametophytic blades were considered a breakthrough in the interspecific hybridization of Porphyra. Organelle genomes (cpDNA and mtDNA) were found to be maternally inherited in the interspecific hybridization by molecular analyses of the organelle DNA. In particular, molecular analyses of nuclear DNA revealed that the surviving F₁ blades were allodiploids in the haploid gametophytic phase; however, there is a possibility of the occurrence of rapid chromosomal locus elimination and rearrangement in the F₁ conchocelis phase. Our findings are noteworthy to the breeding of cultivated Porphyra and will provide important information for understanding of the speciation of marine plants with high species diversity.     

Early development patterns and morphogenesis of blades in four species of <Emphasis Type="Italic">Porphyra</Emphasis> (Bangiales,Rhodophyta)

Pigment mutants were used as genetic markers to study the early development and morphogenesis of blades in four species of Porphyra. In Porphyra haitanensis, P. yezoensis, and P. oligospermatangia, the first two divisions are transverse during conchospore germination, yielding four cells arranged in a line. These species are representative of linear development pattern in Porphyra. Resulting in blades with color sectors vertically arranged. In P. katadai var. hemiphylla, the first division is transverse and the upper cell divides vertically forming two side-by-side cells, and its blades are derived mostly from the upper cell showing a bilateral development pattern with two lateral parts of different colors. In this type of germination, most or the entire blade is derived from the upper cells. Some fronds of P. katadai var. hemiphylla developed in linear pattern. In addition, 9.3% of the conchospore germlings of linear development were produced at 10°C, 15.3% at 15°C, and 38.0% at 20°C for conchospore germlings of P. katadai var. hemiphylla. More linear development occurred at higher temperatures. The results revealed general trends of early developmental patterns and morphogenesis of blades within the genus of Porphyra. Developmental patterns and morphogenesis of blades are under the influence of temperatures.     

Induction and characterization of pigmentation mutants in Porphyra yezoensis (Bangiales, Rhodophyta)

Porphyra yezoensis Ueda conchospore germlings (1–4-cell stages) were treated with N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) for inducing mutations. Three kinds of color-mutated gametophytic blades, which were composed of the mutated cells wholly, sectorially or spottedly, were obtained; and most of them were sectorially variegated blades. The highest frequency of these mutated blades was 1.3%. Four different pigmentation mutant strains were obtained by regenerating single cells and protoplasts that were enzymatically isolated from the mutated sectors of the sectorially variegated blades. The mutants were relatively stable in color in both gametophytic blade and conchocelis phases. In the two phases, each mutant strain showed characteristic differences in the in vivo absorption spectra, and had different pigment contents of major photosynthetic pigments (chlorophyll a, phycoerythrin and phycocyanin) as compared with the wild-type and with each other. The gametophytic blades from the four mutant lines showed significant differences in growth and photosynthetic rates, when they were cultured in the same conditions. By crossing the mutant with the wild-type, it was found that the color phenotypes of two mutants reported above, were resulted from two mutations in different genes, respectively. This revised version was published online in August 2006 with corrections to the Cover Date.     

Analysis of hybridization strains of <Emphasis Type="Italic">Porphyra</Emphasis> based on <Emphasis Type="Italic">rbc</Emphasis>L gene sequences

Two strains, which are the free-living conchocelis of Porphyra yezoensis Ueda and Porphyra haitanensis T. J. Chang et B. F. Zheng, and four “interspecific hybridization” strains of these two species are investigated. The rbcL genes of 11 samples were amplified and sequenced, each of which were about 1,400 bp with a good specificity. The results of pair-wise distance matrix and multi-alignment showed that pair-wise distance were small while homologous index was large between strains Y-2066, Y-k2001, and Y-H001. These two indexes showed the same level as the above between strains H-2001, Y-hyC₁, and Y-hyC₂; however, the distances were larger between three former strains and three latter strains. Cluster trees showed the same trend. Fertile strains appeared after 2 years of culture of unfertile interspecific hybridization conchocelis and were separated from that based on different colors. Our finding that these fertile strains can bear offspring is important for understanding the interspecies hybridization of Porphyra. Molecular analysis of the fertile strains based on rbcL gene showed maternal inheritance. We inferred that somatic recombination was one of the reasons making interspecific hybridization strains fertile.     

Allele-specific marker development and selection efficiencies for both flavonoid 3′-hydroxylase and flavonoid 3′,5′-hydroxylase genes in soybean subgenus soja

Color is one of the phenotypic markers mostly used to study soybean (Glycine max L. Merr.) genetic, molecular and biochemical processes. Two P450-dependent mono-oxygenases, flavonoid 3′-hydroxylase (F3′H; EC1.14.3.21) and flavonoid 3′,5′-hydroxylase (F3′5′H, EC1.14.13.88), both catalyzing the hydroxylation of the B-ring in flavonoids, play an important role in coloration. Previous studies showed that the T locus was a gene encoding F3′H and the W1 locus co-segregated with a gene encoding F3′5′H in soybean. These two genetic loci have identified to control seed coat, flower and pubescence colors. However, the allelic distributions of both F3′H and F3′5′H genes in soybean were unknown. In this study, three novel alleles were identified (two of four alleles for GmF3′H and one of three alleles for GmF3′5′H). A set of gene-tagged markers was developed and verified based on the sequence diversity of all seven alleles. Furthermore, the markers were used to analyze soybean accessions including 170 cultivated soybeans (G. max) from a mini core collection and 102 wild soybeans (G. soja). For both F3′H and F3′5′H, the marker selection efficiencies for pubescence color and flower color were determined. The results showed that one GmF3′H allele explained 92.2 % of the variation in tawny and two gmf3′h alleles explained 63.8 % of the variation in gray pubescence colors. In addition, two GmF3′5′H alleles and one gmF3′5′h allele explained 94.0 % of the variation in purple and 75.3 % in white flowers, respectively. By the combination of the two loci, seed coat color was determined. In total, 90.9 % of accessions possessing both the gmf3′h-b and gmf3′5′h alleles had yellow seed coats. Therefore, seed coat colors are controlled by more than two loci.     

Optimization of conditions for cell cultivation of Porphyra haitanensis conchocelis in a bubble-column bioreactor

Summary Process conditions for cell cultures derived from conchocelis of female red macroalga Porphyra haitanensis were optimized in an illuminated 0.3-l bubble-column photobioreactor, using CO₂ in air as the sole carbon source during a 20-day cultivation period. It reached the highest growth rate when the initial cell density was 700 mg l⁻¹ (dry weight), the optional aeration rate was 1.2 v/v/min, inorganic nitrate concentration was 15 mM and inorganic phosphate concentration was 0.6 mM. This is the first reported bioreactor cultivation study of cell cultures derived from conchocelis of Porphyra haitanensis.     

Observations on the division characterization of diploid nuclear in <Emphasis Type="Italic">Porphyra</Emphasis> (Bangiales,Rhodophyta)

Nuclear divisions of carpospores, conchocelis and conchospores of Porphyra yezoensis, P. haitanensis, P. katadai var. hemiphylla and P. oligospermatangia from China were investigated. The observations showed diploid chromosome numbers of 2n = 6 for P. yezoensis and P. oligospermatangia, and 2n = 10 for P. haitanensis and P. katadai var. hemiphylla. For all four species, somatic pairing of chromosome sets was observed in late prophase. Sister chromosomes separated at anaphase as mitosis took place in carpospores, conchocelis filamentous cells, conchosporangial branch cells and sporangial cells (conchospore formation). Chromosome configurations of tetrad and ring-shaped in conchospore germination were observed, demonstrating the occurrence of meiosis. The characteristics of diploid nuclear division in 2n = 6 species are the same as those of 2n = 10 species. The influence of somatic pairing on nuclear division of diploid cells in Porphyra was discussed.     

Biparental inheritance of chloroplast DNA and the existence of heteroplasmic cells in alfalfa

Summary Mapping of chloroplast DNA (ctDNA) restriction fragment patterns from a chlorophyll deficient mutant and two phenotypically normal alfalfa genotypes (Medicago sativa L.) has demonstrated the existence of a distinct ctDNA genotype from each source. These unique restriction fragment patterns were utilized to identify maternal or paternal origin of ctDNA in hybrid plants from crosses involving the normal alfalfa genotypes as females and the yellow-green chlorophyll deficient sectors as males. Progeny from these crosses expressing the yellow-green sectored phenotypes contained paternal ctDNA in the chlorophyll deficient sectors and maternal ctDNA in the normal sectors, confirming biparental plastid inheritance. The existence of mixed cells containing both mutant and normal plastids at various stages of sorting-out was observed by transmission electron microscopy of mesophyll cells in mosaic tissue from hybrid plants. This observation verified the biparental transmission of plastids in alfalfa.     

PREDICTABILITY AND IRREVERSIBILITY OF GENETIC CHANGES ASSOCIATED WITH FLOWER COLOR EVOLUTION IN PENSTEMON BARBATUS

Two outstanding questions in evolutionary biology are whether, and how often, the genetic basis of phenotypic evolution is predictable; and whether genetic change constrains evolutionary reversibility. We address these questions by studying the genetic basis of red flower color in Penstemon barbatus. The production of red flowers often involves the inactivation of one or both of two anthocyanin pathway genes, Flavonoid 3′,5′‐hydroxylase (F3′5′h) and Flavonoid 3′‐hydroxylase (F3′h). We used gene expression and enzyme function assays to determine that redundant inactivating mutations to F3′5′h underlie the evolution of red flowers in P. barbatus. Comparison of our results to previously characterized shifts from blue to red flowers suggests that the genetic change associated with the evolution of red flowers is predictable: when it involves elimination of F3′5′H activity, functional inactivation or deletion of this gene tends to occur; however, when it involves elimination of F3′H activity, tissue‐specific regulatory substitutions occur and the gene is not functionally inactivated. This pattern is consistent with emerging data from physiological experiments indicating that F3′h may have pleiotropic effects and is thus subject to purifying selection. The multiple, redundant inactivating mutations to F3′5′h suggest that reversal to blue‐purple flowers in this group would be unlikely.     

Isolation and characterization of microsatellite loci from a commercial cultivar of Porphyra haitanensis

Here we report 11 polymorphic microsatellite loci obtained from Porphyra haitanensis through an enriched genomic library. The analysis of 22 individuals from conchocelis phase of P. haitanensis, which possess a diploid nuclear phase, showed that allelic diversity range from three to six alleles. The polymorphism revealed by these loci will be extremely useful for genetic mapping, marker‐assistant selection, germplasm characterization and evolutionary studies in Porphyra.     

Phenolic compounds from Selaginella moellendorfii

Chemical investigation of the leaves and roots of Selaginella moellendorfii Hieron has resulted in the isolation and characterization of two new flavone glucosides, 7‐O‐(β‐glucopyranosyl(1→2)‐[β‐glucopyranosyl(1→6)]‐β‐glucopyranosyl)flavone‐3′,4′,5,7‐tetraol ( 1 ) and 7‐O‐(β‐glucopyranosyl(1→2)‐[β‐glucopyranosyl(1→6)]‐β‐glucopyranosyl)flavone‐4′,5,7‐triol ( 2 ), two new biflavonoids, 2,3‐dihydroflavone‐5,7,4′‐triol‐(3′→8″)‐flavone‐5″,6″,7″,4′′′‐tetraol ( 3 ) and 6‐methylflavone‐5,7,4′‐triol‐(3′→O→4′′′)‐6″‐methylflavone‐5″,7″‐diol ( 4 ), two new lignans, (7′E)‐3,5,3′,5′‐tetramethoxy‐8 : 4′‐oxyneolign‐7′‐ene‐4,9,9′‐triol ( 5 ) and 3,3′‐dimethoxylign‐8′‐ene‐4,4′,9‐triol ( 6 ), together with two known monolignans, four known lignans, and four known biflavonoids. Their structures were established by spectroscopic means and by comparison with literature values.