Marine algal symbionts benefit benthic invertebrate embryos deposited in gelatinous egg masses

Algae colonize the gelatinous egg masses of marine invertebrates. This study demonstrates a symbiotic relationship between marine algae and the invertebrate embryos in gelatinous egg masses found in Indian River Lagoon, FL, USA. The benefits to the embryos in this association differ among host species investigated. The embryos of the polychaete Axiothella mucosa graze on the diatom assemblage in their egg masses and the fitness of the crawl-away juveniles is improved by this food source. The tenuous egg masses of the polychaete Arenicola cristata and the mollusk Haminoea succinea are negatively buoyant when spawned and become buoyant when symbiotic algae are present. In addition to increased dispersal of their lecithotrophic larvae, the potential of the egg masses of A. cristata and H. succinea to float may reduce predation on the embryos by benthic predators such as the gastropod Nassarius vibex. Photosynthetically derived oxygen from the algae may benefit the embryos of the opisthobranch Haminoea elegans by increasing oxygen supply when crawl-away juveniles emerge from the egg mass. However, when mostly earlier stage larvae are hatched from egg masses of H. elegans, the additional oxygen supplied by the algae does not provide a substantial advantage. Algae were absent in the gelatinous egg mass core of only one of the five species examined, Haminoea antillarum. H. antillarum has both a short embryonic development time and denser egg mass gel than the other four species tested. What is not understood is whether invertebrate egg masses are an opportunistic space for algae to colonize or whether only a few microalgal species can exploit the gelatinous substrate.     

SEASONAL PATTERNS OF MORPHOLOGICAL VARIABILITY IN SARGASSUM POLYCERATIUM (PHAEOPHYTA)1

Temporal variability in certain morphological and taxonomically important features was quantified for Sargassum polyceratium Mont. from a population in the Content Keys, Florida (U.S.A.). Patterns of blade development, senescence, and loss caused pronounced seasonal changes in blade length-width ratios. Blade length and width were maximal early in the growing season (August-November) and decreased as the annual stems matured. Early in the growing season, plants had broader blades with randomly distributed cryptostomata. Late in the growing season (February-April), plants had more linear blades with cryptostomata approximately arranged in two rows, one on each side of the midrib. The length-width ratio of blades increased acropetally along the stems and were directly correlated to the size of the cryptostomatal opening and inversely correlated with the number of cryptostomata. The branching pattern of the annual stems ranged from short spur branches to well-developed, lateral axillary branches. The frequency of bifurcated blades increased significantly late in the growing season. Vesicle shape and size and pedicel length were temporally stable. Alated pedicels and mucronate vesicles occurred in low frequencies. The variability of the morphological features used to delineate species within the genus Sargassum on the tropical eastern coasts of the Americas is poorly understood.     

Application of the functional-form model to the culture of seaweeds

Selecting the most appropriate species or strains is an important first step in the development of most algal cultivation systems and is usually a tedious, time-consuming, and expensive step. The functional-form model, first developed to synthesize the adaptive significance of easily assessed thallus-form attributes relative to the productivity and survival of benthic macroalgae, is applicable to the culture of seaweeds and can expedite species or strain selection. The production ecology aspects of the model are useful particularly for applications where the desired product is not species-specific, e.g., systems in which the emphasis is on algal production, such as algal biomass farms and wastewater treatment. A thallus-form with a high surface area: volume ratio is more suited for rapid production and nutrient uptake. The utility of this model to strain selection is demonstrated with the red alga Gracilaria tikvahiae, a species that has been considered a maricultural candidate for a number of utilizations. A continuum of surface area: volume ratios for eight clones of G. tikvahiae showed that this ratio decreased as morphological complexity increased and was a good predictor of both short-term photosynthesis and long-term growth rate. Clones near opposite ends of the surface area: volume ratio spectrum had significant differences for both photosynthesis and growth. Each clone of G. tikvahiae possesses concomitant combinations of benefits as well as costs, which should be carefully evaluated for the cultivation application of interest. Knowledge of functional-form relationships in seaweeds can significantly expedite their successful cultivation.     

UPTAKE OF INORGANIC NITROGEN BY CODIUM FRAGILE SUBSP. TOMENTOSOIDES (CHLOROPHYTA)1

The uptake of nitrate, nitrite and ammonium by Codium fragile subsp. tomentosoides (van Goor) Silva was measured at different combinations of temperature (6–30 C) and irradiance (0–140 μEin.m-^2. s^-1). Uptake of all three forms of N was greater at 12–24 C than at 6 and 30 C. Although uptake was stimulated by light, saturation occurred at relatively low irradiance (7–28 μEin m^-2 s^-1, depending on the N source and temperature). The Michaelis-Menten uptake constants (V_max K)varied with temperature. V_max was greatest at intermediate temperatures and K was lowest at lower temperatures. The V_maxfor NH₄⁺ was higher and the K, for NH₄⁺was lower than those for NO₃^-_- and NO₂^-_-. Codium was capable of simultaneously taking up all three forms of inorganic N although the presence of NH₄⁺ reduced the uptake of both NO₃^-_- and NO₂^-_-. The results of this study indicate that part of the ecological success of Codium in a N-limited environment may be due to its N uptake capabilities.     

Nitrogen release from decomposing seaweeds: species and temperature effects

This study determined the rate at which nitrogen accumulated in seaweeds is released during decomposition and the effect of temperature on their rates of decomposition and nitrogen release. Gracilaria verrucosa and Ulva lactuca decomposed rapidly in outdoor mesocosms. Ulva, but not Gracilaria, became nitrogen-enriched during decomposition. Maximal weekly rates of nitrogen release were 5.91 ± 2.23 and 6.37 ± 2.59 g N m^?2 d^?1, respectively for Gracilaria and Ulva. Temperature had a significant effect on the decomposition rate of Gracilaria in a laboratory experiment: decomposition was greater at 30 °C than at 25 °C. No net decomposition was observed at 16 °C. Gracilaria became nitrogen enriched at 30 °C, but not at 16° or 25°. The release of stored nutrients from decaying seaweeds should be included in nutrient budgets and models when seaweed standing stocks are significant. Seaweed source-sink relationships are important ecologically and can be applied to attempts at using seaweeds as environmental monitors of anthropogenic eutrophication and to efforts of cultivating seaweeds for the improvement of water quality.     

AN UNRECOGNIZED ANCIENT LINEAGE OF GREEN PLANTS PERSISTS IN DEEP MARINE WATERS1

We provide molecular phylogenetic evidence that the obscure genera Palmophyllum Kütz. and Verdigellas D. L. Ballant. et J. N. Norris form a distinct and early diverging lineage of green algae. These palmelloid seaweeds generally persist in deep waters, where grazing pressure and competition for space are reduced. Their distinctness warrants recognition as a new order, the Palmophyllales. Although phylogenetic analyses of both the 18S rRNA gene and two chloroplast genes (atpB and rbcL) are in agreement with a deep‐branching Palmophyllales, the genes are in conflict about its exact phylogenetic placement. Analysis of the nuclear ribosomal DNA allies the Palmophyllales with the prasinophyte genera Prasinococcus and Prasinoderma (Prasinococcales), while the plastid gene phylogeny placed Palmophyllum and Verdigellas as sister clade to all other Chlorophyta.     

MACROALGAL TISSUE NUTRIENTS AS INDICATORS OF NITROGEN AND PHOSPHORUS STATUS IN THE FLORIDA KEYS

This study used the tremendous biochemical and ecological diversity of macroalgae to assess nitrogen and phosphorus availability at a broad, ecosystem‐level scale in the Florida Keys and nearby waters. Spatial variation in tissue nutrients (carbon, C; nitrogen, N; phosphorus, P) of dominant macroalgae were assessed, both as ratios and absolute values, along 12 inshore‐offshore transects in the Florida Keys and at 10 stations in nearby Florida Bay. The resulting detailed analysis demonstrated spatial and temporal patterns in macroalgal tissue nutrients. The transect data revealed no universal inshore‐offshore patterns in tissue nutrients and no obvious “hotspots” of nutrient enrichment. Similarly, when data were compared among segments, there was no universal geographical pattern in tissue nutrients for all species. The most striking result was that the N and P status of macroalgae in Florida Bay was significantly different than other locations. Macroalgae collected from Florida Bay generally had higher N and lower P levels than algae collected elsewhere. The most common inshore‐offshore pattern was higher %N and lower %P availability inshore; however, limited inshore‐offshore differences in N:P ratio suggests that both nutrients were generally readily available in proportional amounts required by the various species. Most species in this study had higher %N, and to a lesser extent, higher %P and %C in March than in July. Based on the published literature on other species of macroalgae, it appears that N and P are generally available in sufficient quantities that most macroalgal growth is not limited by either nutrient.     

3 Phylogenetic affinity of the palmelloid green algae, verdigellas and palmophyllum (chlorophyta), based on analyses of nuclear-encoded small subunit rDNA sequences

Palmophyllum, Verdigellas and Palmoclathrus are marine palmelloid green algae with morphologies ranging from closely adherent crusts, peltate discs, to upright branched thalli. Thalli of these taxa are comprised of small spherical cells embedded within a dense mucilaginous matrix. Taxonomic affinities of these palmelloid genera, however, has remained uncertain. Previous studies of Palmophyllum and Verdigellas classified these algae within the Palmellaceae, but the complete absence of data regarding reproduction have blurred ordinal designations. Generally, these algae have been classified as members of the Tetrasporales within the class Chlorophyceae, but the Chlorococcales has also been proposed. Global analyses of eukaryotic nuclear-encoded small subunit rDNA sequences based on parsimony (MP), neighbor joining (NJ) and likelihood (ML) methods confirm the placement of Palmophyllum and Verdigellas as a monophyletic group within the Chlorophyta, but class and ordinal affinities were not clearly resolved. ML suggested that Verdigellas and Palmophyllum are members of a clade with coccoid prasinophyte algae at the base of the Chlorophyta, while NJ and ML suggested that the palmelloid genera formed a basal lineage of the Viridiplantae. A consistent feature of all analyses, however, is that Verdigellas and Palmophyllum did not group with the chlorophycean orders, Tetrasporales or Chlorococcales. Results will be discussed in the context of taxonomy, character evolution, and implications for green plant evolution. (Supported in part by NSF grants DEB-0128952 to MWF, DEB-0129030 to MAB, and DEB-0128977 to FWZ)