Abstract:Silver nanoparticles, endowed with powerful antimicrobial property, are the most widely used nanomaterial in consumer products, with associated risk of their easy access to environment and freshwater ecosystems by surface runoff. Although toxic effects of nanosilver on bacterial, fungal and mammalian cells have been documented, its impact on algal growth remains unknown. Pithophora oedogonia and Chara vulgaris are predominant members of photosynthetic eukaryotic algae, which form major component of global aquatic ecosystem. Here we report for the first time that nanosilver has significant adverse effects on growth and morphology of these filamentous green algae in a dose-dependent manner. Exposure of algal thalli to increasing concentrations of silver nanoparticles resulted in progressive depletion in algal chlorophyll content, chromosome instability and mitotic disturbance, associated with morphological malformations in algal filaments. SEM micrographs revealed dramatic alterations in cell wall in nanoparticle-treated algae, characterized with cell wall rupture and degradation in Pithophora. Although these observations underscore severe deleterious effects of nanosilver on aquatic environment, the information can also be exploited as a bioengineering strategy to control unwanted and persistent growth of noxious algal weeds that clog the municipal water supply and water channels and produce fouling of water bodies.
Two orders of green alga (Cladophorales and Charales) were investigated for the presence of protein tyrosine kinase activity. Proteins of 70 and 85 kDa were found to be tyrosine phosphorylated in Cladophora fracta, with an additional phosphorylated band evident at the 120-kDa region in Chara vulgaris, suggestive of the presence of putative tyrosine kinase activity in these algal species. A 70-kDa protein was immunoprecipitated from both species using a polyclonal antibody against non-receptor protein tyrosine kinase Syk. The protein was found to be phosphorylated on tyrosine, which was prevented upon pretreatment of algal cells with piceatannol. The extent of phosphorylation directly correlated with algal growth, suggesting a link between Syk kinase activity and growth signaling. These observations supported the presence of Syk-like kinase in the green algal species, which could have critical role in the algal growth and development.
For this purpose, the genotypes were grown under both control (0.0 bar) and stress under drought (-9 bar) condition by using PEG-6000 as osmoticum. The experiment was laid out in an asymmetrical factorial completely randomized design with three replications. Roots, shoots and leaves of ten days old seedlings were harvested and physiological & biochemical analysis were carried out for the above parameters. From the study, it was revealed that relative water content (RWC) and chlorophyll content (chl a, Chl b & total Chl) were reduced, while proline content was increased due to imposition of drought stress with compared to respective control. However, the tolerant genotypes exhibited lower relative reduction for RWC and chlorophyll content and proline content increased more as compared to susceptible ones under drought stress condition. The results suggested that higher levels of RWC, chlorophyll content and proline accumulation in tolerant variety of lentil could play an important role in drought stress tolerance.
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