Copper-induced modifications of the trophic relations in riverine algal-bacterial biofilms.

The effects of copper (Cu) on photosynthetic riverine biofilms were studied in artificial stream channels. Direct effects on the composition and functioning of the biofilms were investigated using plant pigments, community-level physiological profiles (CLPP), and pulse-amplitude-modulated (PAM) fluorescence. Copper caused a significant reduction of microalgal biomass and induced a shift in the population from diatoms to cyanobacteria. However, a decrease in biomass indicated that the replacement of species was not totally effective to counteract the toxic effects of Cu. A direct effect of Cu could also be shown in the bacterial community, and, furthermore, changes in the CLPP could be related to the Cu treatment. Copper-exposed biofilms lost the capacity to use between 11 and 15% of the substrates, but many of the remaining capacities became more robust, indicating an increased Cu tolerance due to the exposure. The change in the biofilm microbial composition points to the indirect effects of Cu on biofilms due to the close interdependence between biofilm autotrophic and heterotrophic compartments. Grazing by snails, which appeared to be an important factor structuring biofilms without any Cu addition, had a very minor effect on Cu-exposed biofilms. Although grazing changed the bacterial composition, its effects were not detected either on the algal community or on the biofilm community tolerance to Cu.

The role of ultraviolet-adaptation of a marine diatom in photoenhanced toxicity of acridine.

Cultures of the marine diatom Phaeodactylum tricornutum were grown under laboratory light with a different fraction of ultraviolet radiation (UV) to study the potential role of photoadaptation in determining the sensitivity to photoenhanced toxicity of acridine. In short-term experiments, a higher acridine concentration was needed to inhibit the photosynthetic electron flux, monitored with chlorophyll a fluorescence, in algae exposed to fluorescent light (low UV) than to mercury light (high UV), consistent with the expected role of UV. The two types of light in long-term exposures led to changes in the pigment composition and photosystem I (PS I) to photosystem II (PS II) stoichiometry to optimize the utilization of fluorescent and mercury light. Despite the adaptation of the photosynthetic apparatus to a small fraction of UV, long-term exposure to mercury light did show a constant sensitivity of the photosynthetic efficiency of P. tricornutum to the phototoxic acridine. It is concluded that the prime receptor of photoenhanced toxicity may be unrelated to the photosynthetic machinery.

Development of photosynthetic biofilms affected by dissolved and sorbed copper in a eutrophic river.

Photosynthetic biofilms are capable of immobilizing important concentrations of metals, therefore reducing bioavailability to organisms. But also metal pollution is believed to produce changes in the microalgal species composition of biofilms. We investigated the changes undergone by natural photosynthetic biofilms from the River Meuse, The Netherlands, under chronic copper (Cu) exposure. The suspended particles in the river water had only a minor effect on reduction of sorption and toxicity of Cu to algae. Biofilms accumulated Cu proportionally to the added concentration, also at the highest concentration used (9 microM Cu). The physiognomy of the biofilms was affected through the growth of the chain-forming diatom Melosira varians, changing from long filaments to short tufts, although species composition was not affected by the Cu exposure. The Cu decreased phosphate uptake and algal biomass measured as chl a, which degraded exponentially in time. Photosynthetic activity was always less sensitive than algal biomass; the photon yield decreased linearly in time. The protective and insulating role of the biofilm, supported by ongoing autotrophic activity, was indicated as essential in resisting metal toxicity. We discuss the hypothesis that the toxic effects of Cu progress almost independently of the species composition, counteracting ongoing growth, and conclude that autotrophic biofilms act as vertical heterogeneous units. Effective feedback mechanisms and density dependence explain several discrepancies observed earlier.

Metal-induced tolerance in the freshwater microbenthic diatom Gomphonema parvulum.

The benthic diatom Gomphonema parvulum Kützing is a common species in both clean and metal contaminated rivers. Our aim was to investigate whether metal-induced tolerance could explain the persistance of this taxon under metal polluted conditions. G. parvulum strains were isolated from a Zn- and Cd-contaminated stream and from a relatively clean ("reference") stream. The strains were cultured in synthetic medium as mono-specific biofilms to maintain their specific benthic growth features. Moreover, the strain from the metal polluted stream was cultured in plain and Zn- and Cd-enriched synthetic medium. Short-term (5 h) toxicity experiments with Zn were performed with the strains using pulse amplitude modulated (PAM) fluorometry. Zn lowered significantly the minimal chlorophyll fluorescence (F0) and the photon yield (phi(p)) of the exposed strains after 5 h exposure. The actual Zn concentrations that caused a 50% reduction (EC50's) of the phi(p) of the strain from the metal polluted stream were significantly higher than those of the isolate from the unpolluted stream. The absence of tolerance to Cu of the "polluted" strain indicated that Zn tolerance resulted from specific induction by chronic exposure to Zn in the field. Observations on field biofilms confirmed a higher tolerance of the G. parvulum population from the polluted stream than of the G. parvulum population from the reference stream. A genetic nature of this metal adaptation was supported by the persistance of the Zn tolerance of the polluted strain 2 years after isolation.

Aplicaciones de los programas multimedia interactivos a la taxonomia y a los estudios de diversidad biológica / The application of interactive multimedia software in taxonomy and biological diversity studies

To study biodiversity and to monitor changes in our biological environmen imperative. At present access to species information and t high quality taxonomic and distributional data are identification keys is limited by the fact that literature is scattered over a vast amount of sources. Exchange of biodiversity data between various researchers is hampered by the lack of universal documentation tools. The introduction of PC's in biological sciences rendered thousands of small and medium sized databases in hundreds of different incompatible formats. Modern multimedia computer techniques, allowing nearly unlimited storage of graphic information in addition to text, will facilitate distribution of easy accessible data. The Linnaeus II software package for biodiversity documentation is an answer to these needs as it presents a universal tool for biologists to document biodiversity and exchange standardized data. Regularly updated electronic monographs on CD-ROM will form the basis for modern, fast accessible libraries