Higher biomolecules yield in phytoplankton under copper exposure

Abstract

[eng] Copper is an important metal for industry, and its toxic threshold in natural ecosystems has increased since the industrial revolution. As an essential nutrient, it is required in minute amounts, being toxic in slightly increased concentrations, causing great biochemical transformation in microalgae. This study aimed at investigating the physiology of Scenedesmus quadricauda, a cosmopolitan species, exposed to copper concentrations including those that trigger intracellular biochemical modifications. The Cu exposure concentrations tested ranged from 0.1 to 25 μM, thus including environmentally important levels. Microalgae cultures were kept under controlled environmental conditions and monitored daily for cell density, in vivo chlorophyll a, and photosynthetic quantum yield (ΦM). After 24h growth, free Cu2+ ions were determined, and after 96h, cellular Cu con- centration, total carbohydrates, proteins, lipids, and cell volume were determined. The results showed that both free Cu2+ ions and cellular Cu increased with Cu increase in culture medium. Microalgae cell abundance and in vivo chlorophyll a were mostly affected at 2.5 μM Cu exposure (3.8 pg Cu cell−1) and above. Approximately 31% decrease of photosynthetic quantum yield was obtained at the highest Cu exposure concentration (25 μM; 25 pg Cu cell−1) in comparison with the control. However, at environmentally relevant copper concentrations (0.5 μM Cu; 0.4 pg Cu cell−1) cell volume increased in comparison with the control. Considering biomolecules accu- mulation per unit cell volume, the highest carbohydrates and proteins yield was obtained at 1.0 μM Cu (1.1 pg Cu cell−1), while for lipids higher Cu was necessary (2.5 μM Cu; 3.8 pg Cu cell−1). This study is a contribution to the understanding of the effects of environmentally significant copper concentrations in the physiology of S. quadricauda, as well as to biotechnological approach to increase biomolecule yield in microalgae production.