Observations on the sterile whorls ofAcetabularia

Summary The sterile whorls ofAcetabularia increase greatly the surface area of the cell. These structures function in the uptake of solutes from the environment. The development of the whorls is controlled by light and also by the availability of nutrients.     

Intracellular calcium redistribution during mating in Chlamydomonas reinhardii

Gametes of the unicellular green alga Chlamydomonas reinhardii recognize and adhere to cells of the opposite mating type by flagellar contact. Adhesion between these specialized organelles signals a rapid series of mating events which result in gamete fusion. The sequence of morphological changes (flagellar tip activation, cell wall loss, and mating structure elongation), which occur as a consequence of the sexual signalling, have been characterized. The signalling mechanisms have, however, not been defined. Calcium is known to be involved during fertilization of animal species. Increased intracellular free calcium, which can be achieved either by calcium influx or by mobilization of ions from intracellular stores, has been observed during activation of both eggs and sperm. A recent report by Bloodgood & Levin that gametes of C. reinhardii preloaded with 45Ca showed a transient increase in Ca efflux following mating, suggests that intracellular Ca redistribution may also accompany mating in this algal species. We have used X-ray microanalysis to analyze the subcellular distribution of bound calcium during mating in Chlamydomonas reinhardii. X-ray maps reveal that calcium is sequestered in discrete granules within the gamete cell body prior to mating and that during activation and cell fusion, calcium is diffuse throughout the cell. This suggests the possibility that calcium serves as a second messenger in this species.     

DEVELOPMENTAL STUDIES IN PORPHYRA (BANGIOPHYCEAE). II. CHARACTERIZATIO OF THE MAJOR LECTIN BINDING GLYCOPROTEINS IN DIFFERENTIATED REGIONS OF THE PORPHYRA PERFORATA THALLUS1

Detergent soluble extracts of differentiated regions of the Porphyra perforata J. Ag. thallus (holdfast, rhizoidal, vegetative and reproductive cells) were fractionated on sodium dodecyl sulfate polyacrylamide gels. Glycoproteins were identified by their lectin affinity. Extracts from all areas of the thallus contained glycoproteins, but the staining patterns were different for each region with each of the lectins tested: concanavalin A, Ulex europeaus agglutinin, Ricinus communis agglutinin, soybean agglutinin and peanut agglutinin. These data indicate that the morphologically distinct regions of the thallus also differ biochemically. Analysis of the lectin blots revealed the presence of tissue-specific glycoproteins in the five thallus areas. Such unique glycoproteins could be used as markers of differentiation in this species.     

Harvesting of Algae by Froth Flotation

A highly efficient froth flotation procedure has been developed for harvesting algae from dilute suspensions. The method does not depend upon the addition of flotants. Harvesting is carried out in a long column containing the feed solution which is aerated from below. A stable column of foam is produced and harvested from a side arm near the top of the column.

The cell concentration of the harvest is a function of pH, aeration rate, aerator porosity, feed concentration, and height of foam in the harvesting column. The economic aspects of this process seem favorable for mass harvesting of algae for food or other purposes.

     

Protoplasts of Gelidium robustum (Rhodophyta)

Viable protoplasts were isolated from apices of the agarophyte Gelidium robustum (Gardn.) Hollenb. & Abb. using a combination of commercial cell-wall degrading enzymes and extracellular wall-degrading enzymes isolated from a marine bacterium. The protoplasts were approximately 8–15 µm in diameter, liberated mainly from the surface cell layers and from cells at the distal ends of medullary filaments. The bacterial enzyme alone was not sufficient to liberate significant numbers of protoplasts. Maximum yield was 9 × 10⁵ protoplasts/g tissue (wet wt.). Optimum osmolality occurred between 1750–1950 mOs kg^–1; yield and viability were severely diminished at osmolalities less than 1350 mOs kg^–1. Viability, as determined by flurorescein diacetate staining and Evans Blue exclusion 1 hr after removal from the enzyme solution, was approximately 80–95%. Roughly 80% of the cells did not show Calcofluor fluorescence, while 40% stained positively for the presence of sulfated polysaccharides. Cell wall regeneration was observed with inconsistent reproducibility, and no cell division was observed when the protoplasts were placed in culture medium.Dedicated to the memory of Professor Michael Neushul.     

Analysis of viability and cell types of macroalgal protoplasts using flow cytometry

The ability to rapidly distinguish viable sub-populations of cells within populations of macroalgal protoplast isolations was demonstrated using flow cytometry. Viable protoplasts from Ulva sp. and Porphyra perforata J. Ag. were distinguished from non-viable protoplasts based on differential fluorescein accumulation. The identities of cortical and epidermal protoplasts from Macrocystis pyrifera (L.) C. Ag. were inferred based on light-scattering and chlorophyll a autofluorescence. Three cell types could be distinguished among protoplasts released from thalli of P. perforata based on chlorophyll a and phycoerythrin autofluorescence. Mixed protoplast populations of Ulva sp. and P. perforata were also discernable based on relative chlorophyll a and phycoerythrin autofluorescence. The ability to screen heterogenous protoplast populations rapidly, combined with the cell sorting capabilities of many flow cytometers, should prove valuable for seaweed biotechnology.     

EFFECTS OF LOW NITROGEN LEVELS AND VARIOUS NITROGEN SOURCES ON GROWTH AND WHORL DEVELOPMENT IN ACETABULARIA (CHLOROPHYTA)1

Nitrate, ammonia, urea, and glycine were compared as nitrogen sources for Acetabularia mediterranea. Cells grew normally in media containing nitrate or urea, while cells did not grow at all when the same amount of N was supplied as ammonium ion. The utilization of glycine remains questionable. Cells in medium without added N (NDM) increased in length and some formed reproductive caps. The whorls of vegetative cells showed considerable hypertrophy in NDM and in glycine. This hypertrophy was due to the elongation of only the first-(a₁) and second- (a₂) order articles. When cut, the basal portion of cells without added N regenerated new apices with whorls. The development of these whorls was inversely proportional to the NO₂ concentration. Analyses showed that the intracellular nitrogen pool in young cells and regenerating bases was very small, about 1/10 of that of fully grown cells. Therefore we suggest that trace amounts of N contaminants in the medium supported growth and development, the uptake of which was facilitated by the hypertrophied whorls, under N-limited conditions.     

DEVELOPMENTAL STUDIES IN PORPHYRA. I. BLADE DIFFERENTIATION IN PORPHYRA PERFORATA AS EXPRESSED BY MORPHOLOGY,ENZYMATIC DIGESTION,AND PROTOPLAST REGENERATION1

Four areas containing different cell morphologies were mapped on Porphyra blades and five different cell types (i.e. tapered with long extensions, large and vacuolated, vegetative and dividing, and reproductive: males and females) were identified in them. Tissues from these areas were dissociated, and protoplasts and single cells were isolated from the dissociated tissue of each distinct region. Regeneration rates of the isolated cells and protoplasts (isolates) varied depending on their morphological type. Regeneration rates were lowest in cultured isolates from the area just above the holdfast (ca. 1 %) and increased gradually to over 80% in isolates from areas of vegetative and reproductive regions away from the holdfast. Four distinct morphological patterns were observed among the regenerating plants. Cells isolated from vegetative areas developed into leafy plants while in liquid culture, and into calli when grown on solid medium. Isolates from reproductive areas developed into either a long thin or short thick filamentous plant. Those from ripe patches of carposporangia developed into thin conchocelis filaments, while isolates from non-differentiated cells bordering the ripe reproductive patches developed into thick filaments resembling the morphology of conchosporangial branches. The blade of Porphyra appears simple as it consists of a single cell layer; however, it is complex both morphologically and physiologically.