PAM fluorometry as a tool to assess microalgal nutrient stress and monitor cellular neutral lipids.

This study investigated the use of Pulse Amplitude Modulated (PAM) fluorometry to measure nutrient induced physiological stress and subsequent synthesis of cellular neutral lipids. A freshwater Chlorella sp. was subjected to complete nutrient stress (distilled H2O) and selective nutrient stress in modified BG-11 media (BG-11-N, BG-11-P and BG-11-Fe). Physiological stress was recorded using parameters, rETR, Fv/Fm, Ek, α and NPQ. Induced stress became evident when these parameters were significantly altered, suggesting the onset of neutral lipid synthesis. Complete nutrient stress induced the highest yield of cellular neutral lipids (∼49%) compared to absence of selected nutrients (∼30%). Physiological stress was recorded by a significant decrease in rETR (75%), Fv/Fm (36%), and Ek (60%) and an increase in NPQ (83%). Optimization of neutral lipids occurred by initially maximizing the biomass and subsequently subjecting the harvested biomass to complete nutrient stress.

Bioprospecting for hyper-lipid producing microalgal strains for sustainable biofuel production.

Global petroleum reserves are shrinking at a fast pace, increasing the demand for alternate fuels. Microalgae have the ability to grow rapidly, and synthesize and accumulate large amounts (approximately 20-50% of dry weight) of neutral lipid stored in cytosolic lipid bodies. A successful and economically viable algae based biofuel industry mainly depends on the selection of appropriate algal strains. The main focus of bioprospecting for microalgae is to identify unique high lipid producing microalgae from different habitats. Indigenous species of microalgae with high lipid yields are especially valuable in the biofuel industry. Isolation, purification and identification of natural microalgal assemblages using conventional techniques is generally time consuming. However, the recent use of micromanipulation as a rapid isolating tool allows for a higher screening throughput. The appropriate media and growth conditions are also important for successful microalgal proliferation. Environmental parameters recorded at the sampling site are necessary to optimize in vitro growth. Identification of species generally requires a combination of morphological and genetic characterization. The selected microalgal strains are grown in upscale systems such as raceway ponds or photobireactors for biomass and lipid production. This paper reviews the recent methodologies adopted for site selection, sampling, strain selection and identification, optimization of cultural conditions for superior lipid yield for biofuel production. Energy generation routes of microalgal lipids and biomass are discussed in detail.

Correlations between metal uptake in the soft tissue of Perna perna and gill filament pathology after exposure to mercury.

The accumulation of metal in soft tissues, filtration rate and gill filament morphology are correlated in the southern African rock mussel, Perna perna, during exposure to mercury (24 days) and recovery (24 days). The amount of Hg in soft tissues increased from 0.13 to 87.5 microg/g dry weight after 24 days exposure, and declined to 13 microg/g during recovery. Mean filtration rate fell from 3,979 to 1,818 ml/h/g dry weight by day 2, but recovered slightly through days 4 and 8 (3,037 ml/h/g), with a higher average rate (5,030 ml/h/g) being maintained over the 24-48 days recovery period. The initial decline in filtration coincided with epithelial cell deterioration presented as interstitial oedema, neural and epithelial cell degeneration and reduced ciliation. Between days 8 and 24, cilia regenerated and there was a general improvement in cell morphology. Gill filament morphology returned to near normal during the metal-free recovery period. The usefulness of P. perna as an indicator of pollution is discussed.

Metal accumulation, filtration and O(2) uptake rates in the mussel Perna perna (Mollusca: Bivalvia) exposed to Hg(2+), Cu(2+) and Zn(2+).

Tissue metal concentrations, filtration and oxygen uptake rates were investigated for Perna perna (Bivalvia: Mollusca) during exposure to Hg(2+), Cu(2+) and Zn(2+) (50 microg/l for 24 days, and 24 days recovery with no metal). Hg and Cu tissue levels increased with exposure time, reaching maximum levels after 24 days (87.5 microg Hg/g dry mass and 45 microg Cu/g dry mass, respectively). Zn levels peaked after 4 days exposure (to 233 microg Zn/g dry mass) and stabilized thereafter. Accumulated metal was rapidly lost from tissues when mussels were returned to uncontaminated seawater, suggesting that tissue concentration data may be of limited use in biomonitoring situations where environmental metals fluctuate to low levels. Filtration rates fell below control rates during Hg(2+) exposure, and became elevated again during the recovery period. Cu(2+) and Zn(2+) exposure had little effect on filtration, but suppressed oxygen uptake. During recovery, oxygen uptake of Cu(2+) and Zn(2+) exposed mussels was elevated above the controls. Filtration and oxygen uptake rates were not correlated, but rather responded in different ways to metal pollution. While these physiological responses of P. perna may be of limited use in biomonitoring, they could indicate how populations may respond to marine pollution.