THE PRODUCTION OF EXTRACELLULAR POLYSACCHARIDE BY THE UNICELLULAR RED ALGA PORPHYRIDIUM AERUGINEUM1,2

The unicellular red alga Porphyridium aerugineum was shown to be encapsulated by an amorphous, water-soluble, polyanionic polysaccharide of high molecular weight. The encapsulating polysaccharide is qualitatively identical with polysaccharide found dissolved in large quantity in the culture medium. The kinetics of extracellular polysaccharide production as a function of cell age was studied. Rates of production (on a per cell basis) of both encapsulating and dissolved polysaccharides are greatest in stationary phase light-grown cultures. Dissolved polysaccharide was quantitatively isolated by precipitation with cetyl pyridinium chloride, conversion to the calcium salt, and reprecipitation with ethanol. The procedure yields a spectrally pure product, which is composed of glucose, galactose, xylose, and 2 undetermined, sugar components, and has a sulfate content of 7.6% by weight. Electron microscopy of Porphyridium revealed that Golgi vesicles transport, polymerized polysaccharides to and through the cell membrane. Similar vesicles were observed in the multicellular Pseudogloiophloea, indicating that the Golgi complex plays a crucial role in the production of extracellular polysaccharides by the red algae. H¹⁴CO₃^- pulse-label experiments resulted in labeled extracellular polysaccharide in which all the constituent components contained ¹⁴C. Rates of excretion of polysaccharide were found, to follow a cyclic pattern, correlated generally with the division cycle, of the cell.     

A FREEZE-ETCHING STUDY OF THE RED ALGA PORPHYRIDIUM

Freeze-etched cells of Porphyridium cruentum and P. aerugineum closely resemble those fixed with glutaraldehyde and post-fixed with osmium tetroxide. Freeze-etching reveals diversity in the non-membranous and membranous parts of the cell. All the membranes are asymmetrical. The application of a double-replica technique illustrates how the two sides of several cell membranes fit together. Interpretation of fracture patterns through the thylakoids and stroma leads to the suggestion that the thylakoids are composed of repeating structural units. A model of the photosynthetic apparatus is proposed. It is suggested that the thylakoids of Porphyridium and other red algae are not always “free” but can be stacked much like those of other plants.     

EFFECT OF ENVIRONMENTAL CONDITIONS ON FATTY ACID COMPOSITION OF THE RED ALGA PORPHYRIDIUM CRUENTUM: CORRELATION TO GROWTH RATE1

The lipid and fatty acid composition of Porphyridium cruentum was determined as a function of light intensity, temperature, pH, and salinity. In cultures cultivated at the optimal temperature under non-limiting light conditions, eicosapentaenoic acid was the main polyunsaturated fatty acid. When growth rate was reduced by decreased light intensity, increased cell concentration, suboptimal temperature, suboptimal pH, or increased salinity, the content of eicosapentaenoic acid decreased and that of arachidonic acid increased, the latter becoming the major polyunsaturated fatty acid.     

艰难梭菌荚膜多糖单糖组成的气相色谱分析

本文对两株艰难梭菌（ＣｄＡ３１８和ＣｄＣＤＣ２７９）荚膜多糖进一步分析,结果证实纯化的艰难梭菌荚膜多糖为单一均匀的物质;经气相色谱分析表明,其单糖组分主要由Ｄ－葡萄糖、Ｄ－甘露糖和Ｄ－半乳糖组成,不同菌株的荚膜多糖可能有微小差异。     

THE CORRELATION OF GOLGI ACTIVITY AND POLYSACCHARIDE SECRETION IN PORPHYRIDIUM12

Quantitative morphometric measurements were made of the area occupied by the Golgi complex in log and stationary phase cells. The technique involved the cutting out and weighing of cellular compartments from electron micrographs of median cell sections. Data from the morphometric measurements combined with physiological measurements of secretory activity yielded a simple model for the involvement of the Golgi complex in the biogenesis of cell surface polysaccharides. Golgi were larger and more numerous in log phase, perhaps indicating a higher rate of polysaccharide synthesis than in stationary phase. In log phase, polysaccharide-containing vesicles accumulate adjacent to the cell membrane. In stationary phase, the polysaccharide is secreted to the cell surface by exocytosis, giving rise to a capsule. Thus the shift from log to stationary phase results in structural and functional cellular differentiation, eg, from a thin to a thick capsule. The ecological implications of capsule formation are discussed.     

VIRUS-LIKE PARTICLES AND NUCLEAR INCLUSIONS IN THE RED ALGA PORPHYRIDIUM PURPUREUM (BORY) DREW ET ROSS1

Ultrastructural examination of the unicellular red alga Porphyridium purpureum has revealed cytoplasmic and nuclear inclusions termed concentrosomes. These bodies are morphologically distinct from the irregular membranous inclusions previously reported by others as concentric bodies. In thin section, the morphology of concentrosomes varies from a simple set of 3 or 4 (or rarely 5) concentrically arranged, electron-opaque, circular profiles to elongate, sinuous forms and particulate aggregations, the majority clearly within the nucleus but separated front the nucleoplasm by what appears to be the nuclear envelope. Although simple concentrosomes may be observed in either the cytoplasm or the nuclei, the more elaborate forms occur only in nuclei. In addition to the concentrosomes, subspherical to polygonal virus-like particles of approximately 40 nm diameter have been observed in P. purpureum. These particles are characterized by an electron-opaque perimeter that, in approximately equal numbers, surrounds an “empty” or an opaque core. Dense arrays of the virus-like particles appear in the cytoplasm but not in the nuclei. Similarities between certain forms of the concentrosomes and the virus-like particles are suggestive of an ontogenetic relationship. The infrequency with which either the concentrosomes or the virus-like particles are observed has hampered attempts to verify a developmental sequence or to establish unequivocally the infectious nature of the virus-like particles.     

THE TOCOPHEROL,VITAMIN K,AND RELATED ISOPRENOID QUINONE COMPOSITION OF A UNICELLULAR RED ALGA (PORPHYRIDIUM CRUENTUM)1

The total lipids of axenically cultivated cells of Porphyridium cruentum were extracted with aqueous methanol-chloroform mixture and fractionated into neutral and polar lipids by silicic acid column chromatography. Thin-layer and reversed-phase paper chromatographic analyses of the neutral lipid fractions revealed the occurrence of plastoquinones (PQ) A and C, vitamin K₁ (K), ubiquinone-10 (Q₁₀), α-tocopherol (α-T), and α-tocopherolquinone (α-TQ) in the photoautotrophically cultured alga, and the same quinones but no tocopherol in the alga grown photoheterotrophically on glycerol. The plastoquinone A and vitamin K₁ were isolated, identified, and estimated by spectroscopic methods. The results indicated the following decreasing order of concentrations: autotrophic culture, PQ A > K > Q₁₀ > PQ C, α-TQ, α-T; heterotrophic culture, PQ A > Q₁₀ > K > PQ C, α-TQ. Except for the absence of plastoquinone B, the overall quinonoid composition was in general agreement with those previously reported for multicellular members of Rhodophyta, but the concentration level in total lipid was markedly lower.     

THE INCORPORATION OF TRITIUM FROM THYMIDINE INTO PROTEINS OF THE MOUSE

Tritium from methyl-H³-thymidine was found to be incorporated into proteins in mice. This incorporation in the mouse as a whole represented between 1 and 10% of the injected tritium. Tritiated water was not an intermediate. Transmethylation reactions are proposed as a means whereby certain amino acids might have acquired the tritium from thymidine at some stage of its catabolism. The initial (2 hr) ratios of DNA to protein tritium activities per milligram of wet tissue ranged from 5 in two tissues of low DNA synthetic activity (pancreas, liver) to 35 to 40 in two tissues of high DNA synthetic activity (spleen, small intestine). Labeled nuclear protein was coincident with labeled DNA in nuclei, where it constituted less than 2.5% of the total tritium. The significance of the findings is discussed.     

A GLYCOPROTEIN NONCOVALENTLY ASSOCIATED WITH CELL‐WALL POLYSACCHARIDE OF THE RED MICROALGA PORPHYRIDIUM SP. (RHODOPHYTA)1

The cells of the red microalga Porphyridium sp. (UTEX 637) are encapsulated in a cell wall of a negatively charged mucilaginous polysaccharide complex composed of 10 different sugars, sulfate, and proteins. In this work, we studied the proteins associated with the cell‐wall polysaccharide. A number of noncovalently associated proteins were resolved by SDS‐PAGE, but no covalently bound proteins were detected. The most prominent protein detected was a 66‐kDa glycoprotein consisting of a polypeptide of approximately 58 kDa and a glycan moiety of approximately 8 kDa containing N‐linked terminal mannose. In size‐exclusion chromatography, the 66‐kDa protein was coeluted with the polysaccharide and could be separated from the polysaccharide only after denaturation of the protein, indicating that the 66‐kDa protein was tightly bound to the polysaccharide. Western blot analysis revealed that the 66‐kDa protein was specific to Porphyridium sp. and P. cruentum, because it was not detected in the other species of red microalgae examined. Indirect immunofluorescence assay confirmed the location of the protein in the algal cell wall. The sequence of cDNA clone encoding the 66‐kDa glycoprotein, detected in our in‐house expressed sequence tag database of Porphyridium sp., revealed that this is a novel protein with no similarity to any protein in the public domain databases and our in‐house expressed sequence tag database of the red microalga Rhodella reticulata. The 66‐kDa protein bound polysaccharides from red algae but not from those of other origins tested. Possible roles of the 66‐kDa protein in the biosynthesis of the polysaccharide are discussed.     

PHYSIOLOGICAL CHARACTERISTICS OF PHOTOSYNTHESIS IN PORPHYRIDIUM CRUENTUM: EVIDENCE FOR BICARBONATE TRANSPORT IN A UNICELLULAR RED ALGA1

Various physiological characteristics of photosynthesis in the unicellular red alga Porphyridium cruentum Naegeli have been investigated. The rate of photosynthesis was optimal at 25° C and pH 7.5 and was not inhibited by 21% oxygen over a temperature range of 5 to 35° C. Kinetics of whole cell photosynthesis as a function of substrate concentration gave a K_1/2, (CO₂) of 0.3 μM. CO₂ compensation point, measured in a closed system at pH 7.5, was a constant 6.7 m?L · L^?1 over the temperature range 15 to 30° C and was unaffected by O₂ concentration. Whole cell photosynthesis, measured in a closed system at alkaline pH, showed that the rates of oxygen evolution were greatly in excess of the rate of CO₂ supply from the spontaneous dehydration of HCO₃^? in the medium. This indicates that bicarbonate is utilized by the cell to support this photosynthetic rate. These physiological characteristics of Porphyridium cruentum are consistent with the hypothesis that this alga transports bicarbonate across the plasmalemma.     

DNA OF THE MARINE RED ALGA GRIFFITHSIA GLOBULIFERA12

A method has been given for isolating nuclei from red algae. The results are given for the isolation, purification, and analysis of Griffithsia globulifera DNA luith several methods. The G-C content is≈42%. A new DNase is also reported.     

INCORPORATION OF KINETIN INTO SALVINIA

The uptake of kinetin-8¹⁴C in the aquatic fern, Salvinia, wascorrelated with an inhibition of stem elongation and floatingleaf expansion. The kinetin-inhibition depended on intact moleculesof kinetin which are incorporated mostly in a supernatant fractioncontaining soluble non-polynucleotides and RNA. Recovery frominhibition occurred when kinetin was depleted from the medium.That portion of the plant which was produced after recoverydid not contain significant levels of kinetin-8¹⁴C. (Received April 18, 1967; )     

THE ULTRASTRUCTURE OF GALLS ON THE RED ALGA GRACILARIA EPIHIPPISORA1

A strain of Gracilaria epihippisora Hoyle produces gall-like cell proliferations in culture. These growths can be excised and grown separately, where they retain an undifferentiated morphology and reach 5mm in diameter. The gall tissue consists of a single morphological cell type without any differentiation between surface and internal cells as is characteristic of normal thallus tissue. Gall cells are typically 20–40 μm in diameter and contain the usual complement of organelles and a prominent vacuole, although there are several distinct features. The large multilobed plastids have an extensive proliferation of thylakoid membranes, which form an arrangement of loops and spirals. The thallus outer cell wall layer is highly reduced. The gall growths contain intracellular virus-like particles (ca. 80 nm in diameter) that occur in discrete groups.     

FLORIDOSIDE AS A CARBON PRECURSOR FOR THE SYNTHESIS OF CELL‐WALL POLYSACCHARIDE IN THE RED MICROALGA PORPHYRIDIUM SP. (RHODOPHYTA)1

Although red algae are known to be obligatory photoautotrophs, the red microalga Porphyridium sp. was shown to assimilate and metabolize floridoside. A pulse‐chase experiment with [¹⁴C]floridoside showed that at the end of a 240‐min pulse, 70% of total ¹⁴C‐uptake by the cells remained in the floridoside fraction. To evaluate the assimilation of floridoside by Porphyridium sp. cells, we exposed Porphyridium sp. not only to [¹⁴C]floridoside but also to its constituents, [¹⁴C]glycerol and [¹⁴C]galactose, as compared with [¹⁴C]bicarbonate. The extent of incorporation of [¹⁴C] galactose by the Porphyridium sp. cells was insignificant (50–80 dpm·mL^?1), whereas uptake of ¹⁴C from [¹⁴C]glycerol into the algal cells was evident (2.4 × 10³ dpm·mL^?1) after 60 min of the pulse. The pattern of ¹⁴C distribution among the major constituent sugars, xylose, glucose and galactose, of the labeled soluble polysaccharide was dependent on the ¹⁴C source. The relative content of [¹⁴C]galactose in the soluble polysaccharide was highest (28.8%) for [¹⁴C]floridoside‐labeled culture and lowest (19.8%) for the [¹⁴C]glycerol‐labeled culture. Upon incubation of [¹⁴C]floridoside with a crude extract of a cell‐free system prepared from nonlabeled cells of Porphyridium sp., the label was indeed found to be incorporated into the sulfated polysaccharide. Our results suggested that the carbon metabolic pathway in Porphyridium sp. passes through the low molecular weight photoassimilatory product—floridoside—toward sulfated cell‐wall polysaccharide production.     

ULTRASTRUCTURE OF THE CONCHOCELIS STAGE OF THE MARINE RED ALGA PORPHYRA LEUCOSTICTA1

The ultrastructure of the Conchocelis or filamentous stage of Porphyra leucosticta was investigated. Each cell contains 1 or 2 parietal, stellate chloroplasts with a single pyrenoid in each chloroplast. The centrally located nucleus is irregularly shaped and contains 1–2 nucleoli. The cytoplasm has typical floridean starch grains and nonmernbrane-bound lipid bodies. The cell wall is divided into an outer and an inner wall. Many lomasomes are associated with the cell membrane. Pit connections are found between cells, and their taxonomic significance is discussed.