Purification of α-1,4-glucan lyase from red algae and fungi has previously been reported. The α-glucan lyase converts α-glucans to 1,5-anhydro-D-fructose. In this study, an endophyte was detected between the algal cells of Gracilariopsis sp., but not penetrating the cell walls. Histological staining was consistent with the endophyte being fungal and immunohistochemistry revealed that it possessed an α-1,4-glucan lyase differing from that of the host. The endophyte α-glucan lyase was recognized by antisera against both fungal and red algal α-glucan lyases, whereas the α-glucan lyase found in the algal tissue was recognized only by the antisera against algal α-glucan lyase. The lyases occur independently in the host and in the endophyte, and were sometimes detected simultaneously. The endophyte was only observed in Gracilariopsis sp. collected in China; no endophyte could be detected in Gracilariopsis sp. from California or in Gracilaria chilensis.

The allogamous raphid diatom Achnanthes longipes C. A. Agardh possesses a complex breeding system involving interactions between three types of clone: monoecious, unisexual and bisexual. Previous studies showed that these three types can be crossed with each other, with a tendency for sexual characteristics to be inherited: inbred monoecious lineages gave rise to monoecious or, very rarely, to bisexual clones, while inbred unisexual lineages yielded unisexual and bisexual clones. The current paper reports on the progeny of crosses between monoecious and unisexual clones and their inbred offspring. All three types of clone appeared in the F1 and F2, although unisexual clones of opposite sex to the parental clone were not found. Inbreeding depression was observed and also a tendency for ‘normal’ auxosporulation (producing two auxospores per pair of gametangia) to be replaced by ‘reduced’ or ‘intermediate’ auxosporulation (producing one auxospore per pair). In addition, patterns of incompatibility were observed that were not seen during earlier studies of clones isolated directly from nature. These included the inability of some F1 clones to mate with each other, in spite of compatibility with all other clones examined (unisexual, bisexual and monoecious).

Eight Cocconeis Ehrenberg taxa (species and varieties) epiphytic on the leaves of Posidonia oceanica (L.) Delile were studied by scanning and transmission electron microscopy. Samples of Posidonia oceanica were collected throughout the year from seagrass meadows around the island of Ischia (Gulf of Naples, Italy). On the basis of some peculiar ultrastructural characteristics of the valve areolation, a new species, Cocconeis multiperforata sp. nov., and two new varieties, C. neothumensis var. marina var. nov., and C. scutellum var. posidoniae var. nov., are described. Ultrastructural analysis also revealed new morphological characteristics in C. britannica Naegeli in Kützing and C. maxima (Grunow) Peragallo & Peragallo, and confirmed observations of other authors for C. molesta var. crucifera Grunow, C. pellucida Grunow in Rabenhorst and C. stauroneiformis (Rabenhorst) Okuno. Our observations on the abundance of the different species provide new information on their distribution and ecology.

The physiological adaptation of the phosphate uptake behaviour of the cyanobacterium Anacystis nidulans (Synechococcus leopoliensis) has been studied under phosphate-deficient conditions. We show that, during additions of pulses of phosphate, the individual cells of a population potentially develop a coherent behaviour with respect to the kinetic and energetic properties of the high-affinity phosphate uptake system. These adaptive responses are independent of the amount of stored phosphate and the absolute external phosphate concentration, but depend on the exposure time to elevated phosphate concentrations. We demonstrate that the response to additions of pulses of phosphate triggers further metabolic alterations to CO2 fixation, and the flow of fixed carbon into the pool of low-molecular weight-compounds or glycogen. These alterations may also affect subsequent growth. The ecological relevance of the adaptive phosphate uptake behaviour is discussed with respect to the establishment and stability of natural communities.

The phosphate uptake behaviour of phytoplankton communities in two eutrophic Uruguayan lakes has been studied using [32p]phosphate. In order to measure net incorporation of this tracer, lake samples were prelabelled with successive pulses of radioactive phosphate prior to the uptake experiments proper. The data were analysed using a proportional flow-force relationship which allows the evaluation of two characteristic parameters: a conductivity coefficient LP that here reflects the overall activity of the uptake systems of the community, and a threshold concentration [Pe]A at which net incorporation of phosphate ceases for energetic reasons. Between December 1997 and July 1998 in Lago Rodo phosphate supply by inflowing groundwater was periodically interrupted resulting in distinct states of phosphate deficiency. This showed that the phytoplankton responded to alterations in the phosphorus status of the lake by characteristic changes in LP and [Pe]A. The uptake behaviour of the phytoplankton community thus obeyed the linear flow-force relationship over a wide concentration range, in contrast to expectations of non-equilibrium thermodynamics. The observed uptake characteristics exhibited by multi-species phytoplankton ensembles are discussed with respect to a possible coherent behaviour of the constituents of these communities.

Cyanobacteria are often the dominant phototrophs in high-latitude lakes and streams where they must experience continuously low temperature and extreme variations in daylength. The present study examined the interaction between these two variables for the growth and physiology of an Arctic isolate of the mat-forming species Schizothrix calcicola (Agardh) Gomont. Growth rates (μ), photosynthesis (P), respiration (R), pigment composition and in vivo absorption characteristics were measured under 15 combinations of daylengths (8[ratio ]16, 12[ratio ]12, 16[ratio ]8, 20[ratio ]4 and 24[ratio ]0 L/D) and temperatures (5, 15 and 25 °C). μ increased with increasing temperature (μmax at 5 °C = 0·12 d−1, μmax at 25 °C = 0·28 d−1) and a similar trend was observed in photosynthetic capacity (average PBmax at 5 °C = 4·42 mg C (mg Chl a)−1 h−1, average PBmax at 25 °C = 5·74 mg C (mg Chl a)−1 h−1), pigment content and absorbance. Daylength had a positive effect on μ and pigment absorption, but not pigment content. The shape of the μ–daylength curve varied with temperature: μ was a linear function of daylength at 5 °C, but at 15 and 25 °C the relationship resembled a rectangular hyperbola and μ saturated at 16[ratio ]8 and 12[ratio ]12 L/D, respectively. The non-linear relationship between μ and daylength at high temperature was related to a reduction in net photosynthesis under extended daylength; at 25 °C, net P under 24[ratio ]0 L/D was 0·82±0·37 mg O2 (mg Chl a)-1 h−1, while under 8[ratio ]16 L/D, it was 6·54±0·69 mg O2 (mg Chl a)−1 h−1. The constant increase in growth with increasing daylength at low temperature may reflect an adaptive tolerance to the combination of cold temperature and continuous daylight during the Arctic summer.

A phylogenetic analysis was conducted on 21 biraphid naviculoid diatom species (from three orders and five families, using 5 protoplast and 21 frustule characters) to test whether the recently described genus Craspedostauros was more closely related to members of the Mastogloiaceae or to other stauros-bearing diatoms. The analysis also tested, and confirmed, the hypothesis that the stauros, as recognized by light microscopy, is a homoplastic character. Whereas partitioned analyses of protoplast and frustule data resolved different parts of the ‘total’ tree, using NONA parsimony analysis of all the data, one tree was obtained. This tree placed Craspedostauros in the mastogloialean clade, rather than near Stauroneis, Staurophora, Haslea or Meuniera. The ordinal and familial groupings suggested by Round and others were also confirmed by the analysis, supported particularly by protoplast and some ultrastructural features.

A novel member of the Calyptrosphaeraceae surrounded by a hyaline sheath, with only one chloroplast and without an emergent haptonema, is tentatively described as a species of Calyptrosphaera Lohmann. It has an interrupted body to its single pyrenoid and a unique microtubular root complement with only one crystalline root (CR) nucleating on root 2 (R2). At preprophase it produces a CR1, lending support to the idea that these crystalline roots contribute to the mitotic spindle. It shares numerous ultrastructural traits with the heterococcolithophorid Cruciplacolithus neohelis but, although it is tempting to consider it a haploid phase of this organism, is distinct from it.

In this study we tested the hypothesis that iron limitation suppresses photoacclimation in cultures of the Antarctic flagellate Pyramimonas sp. The cultures were exposed to two different irradiances under iron-rich and iron-poor conditions. Light-harvesting capacity was determined by assessing the pigment composition and measuring in vivo absorption spectra. Light utilization efficiency (α) was determined from photosynthesis versus irradiance curves. The quantum yield of photosynthesis (ϕm) was calculated using α and the absorption spectra. Iron limitation led to commonly observed changes in cells of Pyramimonas, that is, a decrease in cellular pigment content and a reduction in cellular carbon and nitrogen quota. A reduction in αcell followed a decrease in ϕm and light-harvesting capacity. Interpretation of the effects of iron limitation was different when considered on a carbon basis. Because iron limitation resulted in a decrease in cellular carbon content, the carbon-specific absorption coefficient was not affected. Consequently, the observed decrease in αC was mainly due to the decrease in ϕm, showing that iron limitation did not control light utilization via pigment synthesis but exerted control on energy transfer. This is supported by the findings that at high irradiance a shift in pigment ratios within the total pool of violaxanthin, antheraxanthin and zeaxanthin towards zeaxanthin, which is indicative of photoacclimation to high irradiance, was observed for iron-replete cells as well as for iron-depleted cells. In contrast to what is generally hypothesized, the effects of iron limitation were not enhanced at low irradiance. Low irradiance led to an increase in the cellular light-harvesting pigment content. This increase was less pronounced in iron-depleted cells than in iron-replete cells. However, looking at the light-harvesting capacity of the cells on a carbon basis, it was found that iron-depleted cells responded similarly to iron-replete cells. We therefore conclude that the light-harvesting capacity was governed by light conditions and not by iron limitation. In addition to the increase in absorption capacity at low irradiance, an increase in light utilization efficiency was measured, again under both iron-rich and iron-poor conditions. Notably, the relative increase in αC was strongest in iron-depleted cells. Photoacclimation was clearly demonstrated by normalizing α to chl a. For iron-replete cells, αchl was highest at high irradiance. In contrast, for iron-depleted cells αchl was highest at low irradiance. We argue that iron-depleted cells can photoacclimate to low irradiance by a reduction in the ‘package effect’ and reducing growth rates.